BIO 1010 Chapter 8 Leaves PDF
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This document is an educational resource on the topic of leaves, discussing their various elements, functions, and structural specifics. It describes multiple leaf types, including simple and compound leaves.
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Chapter 8 Leaves Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Introduction All leaves originate as primordia in buds. At maturity, most leaves have: Stalk = petiole – Leaves sessile if lacking petiole (monocots) Flattened blade = lamina Network of...
Chapter 8 Leaves Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Introduction All leaves originate as primordia in buds. At maturity, most leaves have: Stalk = petiole – Leaves sessile if lacking petiole (monocots) Flattened blade = lamina Network of veins = vascular bundles Stipules at base of petiole Flowering plants leaves associated with leaf gaps and have axillary buds at base. Leaves may be simple or compound. Simple leaves - With a single blade Compound leaves - Blade divided into leaflets Pinnately compound leaves - Leaflets in pairs along rachis (petiole) – Bipinnately compound leaf Bipinnately compound leaf Leaflets subdivided Palmately compound leaves - All leaflets attached at same point at end of petiole. Palmately compound leaf Leaf Shapes Leaf Shapes Leaves: Biological Solar Panels Green leaves capture light energy by means of photosynthesis. Photosynthesis - Trapping and storing of energy in sugar molecules that are constructed from water and carbon dioxide Stomata - Tiny pores on lower surfaces of leaves Allow carbon dioxide to enter and oxygen to diffuse out Water vapor also escapes via stomata. – Guard Cells control water loss by opening or closing pore of stomatal apparatus. Other functions of leaves: Wastes from metabolic processes accumulate in leaves and are disposed of when leaves are shed. Play major role in movement of water absorbed by roots – Transpiration occurs when water evaporates from leaf surface. (SPAC) Other functions of leaves: Guttation - Root pressure forces water out hydathodes (secretory tissue) at tips of leaf veins in some plants. Leaf Arrangements and Types Leaves are attached to stems at nodes, with stem regions between known as internodes. Phyllotaxy - Arrangement of leaves on stem – Alternate - One leaf per node – Opposite - Two leaves per node – Whorled - Three of more leaves at a node Alternate Opposite Whorled Leaf Arrangements and Types Venation - Arrangement of veins in a leaf or leaflet blade Pinnately veined leaves - Main midvein included within enlarged midrib. – Secondary veins branch from midvein. Palmately veined leaves - Several primary veins fan out from base of blade. Pinnate venation (Tulip poplar) Palmate venation (Maple) Leaf Arrangements and Types Monocots - Primary veins parallel = Parallel venation Dicots - Primary veins divergent in various ways = netted or reticulate venation. Dichotomous venation - Veins fork evenly and progressively from base of blade. Parallel venation Reticulate venation Dichotomous venation Palmate venation (dicot) Pinnate venation (dicot) Parallel venation (monocot) Dichotomous venation (gymnosperm) Internal Structure of Leaves Three regions: Epidermis, mesophyll, veins (vascular bundles) Epidermis - Single layer of cells covering the entire surface of the leaf Devoid of chloroplasts Coated with cuticle (with cutin) Functions to protect tissues inside leaves Waste materials may accumulate in epidermal cells. Different types of glands may also be present in the epidermis. Stomata Lower epidermis typically has thinner layer of cutin and is perforated by numerous stomata. Stomata bordered by two guard cells. – Guard cells originate from the same parent cell, and contain chloroplasts. o Primary functions: « Regulate gas exchange between leaf interior and atmosphere « Regulate evaporation of water o Changes in amount of water and ion concentration in guard cells cause them to inflate or deflate. « Inflate - Stomata open « Deflate - Stomata close o Location: « Adaxial – top (upper) epidermis « Abaxial – bottom (lower) epidermis **** Mesophyll and Veins Most photosynthesis takes place in the mesophyll between the two epidermal layers. Palisade Mesophyll – – Compactly stacked, barrelshaped parenchyma cells, commonly in two rows Contains most of leaf’s chloroplasts Spongy Mesophyll – Loosely arranged parenchyma cells with abundant air spaces Mesophyll and Veins Veins (vascular bundles) are scattered throughout mesophyll. Consist of xylem and phloem tissues surrounded by bundle sheath of thicker-walled parenchyma Mesophyll and Veins Monocots have some differences: Usually do not have mesophyll differentiated into palisade and spongy layers Often have bulliform cells on either side of main central vein – Bulliform cells partly collapse under dry conditions. o Causes leaf to fold or roll, reducing transpiration Monocot leaf cross section Collapsing Bulliform Cells = Rolled Blade Turgid Bulliform = Open Blade Shade Leaves Specialized Leaves Receive less total light than sun leaves Compared to sun leaves, shade leaves: – Tend to be larger and thinner – fewer welldefined mesophyll layers and fewer chloroplasts – Have fewer hairs Specialized Leaves: Sun vs. Shade Leaves Sun Shade Specialized Leaves Leaves of Arid Regions limited availability of water, wide temperature ranges, and high light intensities. Leaves reduce loss of water by: – – – – Thick, leathery leaves Fewer stomata or sunken stomata Succulent, waterretaining leaves, or no leaves Dense, hairy coverings Specialized Leaves Leaves of Aquatic Areas Less xylem and phloem Mesophyll not differentiated into palisade and spongy layers. Large air spaces Specialized Leaves Tendrils Modified leaves that curl around more rigid objects, helping the plant to climb or to support weak stems Garden peas – Tendrils Spines Modified leaves that reduce leaf surface and water loss, and protect from herbivory. – Cacti o Leaf tissue replaced with sclerenchyma. o Photosynthesis occurs in stems. Spine Specialized Stems Thorns - Modified stems arising in the axils of leaves of woody plants Thorn Prickles Outgrowths from epidermis or cortex Specialized Leaves Storage leaves Succulent leaves are modified for water storage. – Have parenchyma cells with large vacuoles – Many desert plants Fleshy leaves store carbohydrates. – Onions, lily Specialized Leaves Flower-Pot Leaves Leaves develop into urn- like pouches that become home of ant colonies. Ants carry in soil and add nitrogenous wastes that provide good growing medium for the plant’s own roots. – Dischidia, an epiphyte of Australia Flower-pot leaf sliced lengthwise Window leaves Specialized Leaves In succulent desert plants of Africa Leaves buried in ground, except for exposed end. – – Longitudinal section End has transparent, thick epidermis and Haworthia emelyae var. comptoniana transparent water storage cells underneath. Allows light into leaf, while buried leaves keep plant from drying out Fenestria aurantica Frithia pulchra Specialized Leaves Reproductive Leaves Walking fern - New plants at leaf tips Mother of thousands- Tiny plantlets along leaf margins Specialized Leaves Floral Leaves (bracts) At bases of flowers or flower stalks Poinsettia - Flowers do not have petals, instead brightly colored bracts surround flowers. Clary’s sage - Colorful bracts are at top of flowering stalks above flowers. Poinsettia Clary’s sage Bougainvillea sp. Specialized Leaves Floral Leaves (bracts) Specialized Leaves Insect-Trapping Leaves Grow in swampy areas and bogs – Nitrogen and other elements are deficient in soil. o Specialized leaves trap and digest insects. Pitcher Plants – Insects trapped and digested inside coneshaped leaves. Pitcher plant Specialized Leaves Insect-Trapping Leaves Sundews – Have round to oval leaves covered with glandular hairs that have a sticky fluid of digestive enzymes at tip Venus’s Flytraps – Only in North Carolina and South Carolina – Blade halves trap insects. Specialized Leaves Insect-Trapping Leaves Bladderworts – Submerged or floating in shallow water – Tiny bladders on leaves have trap doors that trap insects inside bladders. Specialized Leaves https://www.youtube.com/watch?v=vqVL92uq1OE Autumnal Changes in Leaf Color Chloroplasts of mature leaves contain several groups of pigments: Chlorophylls - Green Carotenoids - Yellows In fall, chlorophylls break down and other colors are revealed. Water soluble anthocyanins (red or blue) and betacyanins (red) may also be present in the vacuole. Abscission Deciduous plants drop leaves seasonally Senescence: collective aging and decline process. Abscission - Process by which leaves are shed Occurs as a result of changes in abscission zone near base of petiole – Protective layer o – Cells coated and impregnated with suberin. Separation layer o Pectins in middle lamella of cells are broken down by enzymes. Human and Ecological Relevance of Leaves Landscaping - Shade trees Food - Cabbage, lettuce, celery petioles, spices Dyes Perfumes - Oils of orange tree, lavender Ropes and Twine - Agave, hemp fibers Drugs - Narcotics, tobacco, marijuana Beverages - Tea, tequila (agave leaves) Insecticides - Rotenone Waxes - Carnauba and caussu waxes Aesthetics - Floral arrangements, gardens Review Introduction Leaf Arrangements and Types Internal Structure of Leaves Stomata Mesophyll and Veins Specialized Leaves Autumnal Changes in Leaf Color Abscission Human and Ecological Relevance of Leaves