Leaf structure and function
Download as PPTX, PDF12 likes11,370 views
This document discusses leaf structure and modifications in plants. It begins by describing the general form of leaves, including the blade and petiole. It then covers leaf types like compound and simple leaves. The document discusses leaf arrangement on stems, including opposite, spiral and whorled patterns. It also covers venation patterns and how they differ between monocots and dicots. The rest of the document details specialized leaf structures like tendrils, cotyledons, and modified leaves that carry out functions like photosynthesis, insect trapping, or defense.
Leaf structure and function
- 1. Leaf structure and some modifications Course instructor, Ms. Varsha Gaitonde (Ph.D. student) Course: Introductory Biology UGS-111 For: BSC (Agri) students, BHU, Varanasi
- 2. General leaf form • Leaves are the main photosynthetic organs of most plants – but green stems are also photosynthetic. – While leaves vary extensively in form, they generally consist of a flattened blade and a stalk, the petiole, which joins the leaf to a stem node. – In the absence of petioles in grasses and many other monocots, the base of the leaf forms a sheath that envelops the stem. • Most monocots have parallel major veins that run the length of the blade, while dicot leaves have a multi branched network of major veins. Blade Petiole
- 3. Stipule
- 7. Leaf types – Pinnately & Palmately Compound Leaves
- 11. Whorled
- 13. Leaf Arrangement on the Stem Opposite: 2 leaves at a node, on opposite sides of the stem Spiral: 1 leaf per node, with the second leaf being above the first but attached on the opposite side of the stem Whorled: 3 or more leaves at a node
- 14. • Plant taxonomists use leaf shape, spatial arrangement of leaves, and the pattern of veins to help identify and classify plants. – A Simple leaves have a single, undivided blade, while compound leaves have several leaflets attached to the petiole. – A Compound leaf has a bud where its petiole attaches to the stem, not at the base of the leaflets. Leaf Arrangement on the Stem
- 15. Venation = arrangement of veins in a leaf • Netted-venation = one or a few prominent midveins from which smaller minor veins branch into a meshed network; • common to dicots and some nonflowering plants. • Pinnately-veined leaves = main vein called midrib with secondary veins branching from it (e.g., elm). • Palmately-veined leaves = veins radiate out of base of blade (e.g., maple).
- 16. Venation = arrangement of veins in a leaf •Parallel venation = characteristics of many monocots (e.g., grasses, cereal grains); veins are parallel to one another. •Dichotomous venation = no midrib or large veins; rather individual veins have a tendency to fork evenly from the base of the blade to the opposite
- 17. Most dicots have branch-like veins and palmate leaf shape Monocots have parallel leaf veins and longer, slender blades Leaves - Comparisons Monocots and dicots differ in the arrangement of veins, the vascular tissue of leaves
- 18. Specialized or Modified Leaves • Drought-resistant leaves = thick, sunken stomata, often reduced in size • In American cacti and African euphorbs, leaves are often reduced such that they serve as spine to discourage herbivory and reduce water loss • The stems serve as the primary organ of photosynthesis.
- 19. Specialized or Modified Leaves • In pine trees, the leaves are adapted to living in a dry environment too. • Water is locked up as ice during significant portions of the year and therefore not available to the plant; pine leaves possess • sunken stomata, • thick cuticles • needle-like leaves • hypodermis, which is an extra cells just underneath the epidermis –
- 20. Cotyledons or “seed leaves” First leaves produced by a germinating seed Often contain a store of food (obtained from the endosperm) to help the seedling become established.
- 21. Tendrils Garden Pea Tendrils - blade of leaves or leaflets are reduced in size, allows plant to cling to other objects (e.g., sweet pea and garden peas.
- 22. Figure 11.8 (1) Specialized Leaves • Some plants obtain nitrogen from digesting animals (mostly insects). • The Pitcher plant has digestive enzymes at the bottom of the trap • This is a “passive trap” Insects fall in and can not get out • Pitcher plants have specialized vascular network to tame the amino acids from the digested insects to the rest of the plant
- 23. Figure 11.12 (2)Specialized Leaves • The Venus fly trap has an “active trap” • Good control over turgor pressure in each plant cell. • When the trap is sprung, ion channels open and water moves rapidly out of the cells. • Turgor drops and the leaves slam shut • Digestive enzymes take over
- 24. Leaves as Needles and Spines
- 25. Leaves as Colorful Bracts