Plant Structure and Function - Chapter 28 and 29 PDF
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This document is a plant biology chapter, including the structure and growth of plants, roots, stems and leaves, and vascular tissue systems. It also includes details about photosynthesis, transpiration, and sugar transport. Information on different plant types like monocots and eudicots is also covered.
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Chapter 28 Plant Structure and Growth https://parade.com/23643/linzlowe/what-the-heck-is-romanesco-and-how-do- you-cook-it/ Romanesco Angiosperms (flowering plants) Two major clades: Monocots – one seed leaf (cotyledons)...
Chapter 28 Plant Structure and Growth https://parade.com/23643/linzlowe/what-the-heck-is-romanesco-and-how-do- you-cook-it/ Romanesco Angiosperms (flowering plants) Two major clades: Monocots – one seed leaf (cotyledons) Eudicots – two seed leaves Fig. 28.2 Concept 28.1: Plants have a hierarchical organization consisting of organs, tissues, and cells Plants organs organ several types of tissues that do a job tissue one or more cell types that do a job © 2014 Pearson Education, Inc. The Three Basic Plant Organs: Roots, Stems, and Leaves Plant body: takes water and minerals from below ground and takes CO2 and light from above ground © 2014 Pearson Education, Inc. root system plant’s roots. Underground; sugar from leaves ‘feeds’ roots. shoot system stems, leaves, and flowers; water and minerals absorbed by the root system is transported to the shoots. Roots Anchors plant, absorbs minerals and water, and stores carbohydrates. root systems Taproot Eudicots; main vertical root and lateral roots branching off the taproot © 2014 Pearson Education, Inc. root systems Fibrous Monocots; mat of thin roots all about the same size; adventitious or arise from stems and leaves © 2014 Pearson Education, Inc. Stems have leaves and buds; elongate and orient shoots to maximize photosynthesis Nodes where leaves attach Internodes segments between nodes Fig 28.3 apical bud compact series of nodes and internodes near the shoot tip axillary bud in upper angle formed by the leaf and the stem; generally dormant but can form a lateral branch, thorn, or flower modified stems Horizontal shoot that grows just below surface Horizontal shoots along the surface with little plantlets at each node. Enlarged ends of rhizomes Fig 28..6 to store food; eyes of potatoes are axillary buds! Leaves main photosynthetic organ; allow gas exchange, dissipation of heat, and defense flattened blade; stalk = petiole, joins leaf to the stem veins vascular tissue of leaves Monocots parallel veins Eudicots branching veins modified leaves Fig 28.7 Dermal, Vascular, and Ground Tissue Systems vascular tissue system transport of materials; mechanical support Fig 28.8 Dermal, Vascular, and Ground Tissue Systems vascular tissues xylem conducts water and dissolved minerals from roots into the shoots phloem transports organic nutrients from where they are made to where needed Stele vascular tissue of a root or stem Angiosperms = solid central region stele of stems and leaves is divided into vascular bundles, strands of xylem and phloem © 2014 Pearson Education, Inc. dermal tissue system outer protective covering nonwoody plants epidermis outer layer of cells cuticle waxy coating; prevents water loss woody plants periderm replaces epidermis in older regions of stems and roots; protective layer Ground tissue system tissues that are neither dermal nor vascular ground tissue is internal to the vascular tissue = pith ground tissue is external to the vascular tissue = cortex. includes cells specialized for photosynthesis, short- distance transport, storage, or support Common Types of Plant Cells Parenchyma Collenchyma Sclerenchyma Water-conducting cells of the xylem Sugar-conducting cells of the phloem Parenchyma cells Thin, flexible primary walls Lack secondary walls large central vacuole Perform the most metabolic functions Photosynthesis can divide and differentiate Collenchyma cells grouped in strands thicker and uneven cell walls Lack secondary walls flexible support http://emp.byui.edu/wellerg/Cell%20Types%20and%20Tissues%20Lab/ Instructions/Cell%20Types%20and%20Tissues%20Lab%20Instructions Sclerenchyma cells Rigid; secondary walls contain lignin, a strengthening polymer dead at functional maturity Sclerenchyma cells Two types Sclereids short and irregular; thick Fibers long, slender; grouped in strands Materials used in textiles (fabrics, paper, etc.) Water-conducting cells of the xylem dead at maturity Two types Tracheids long, thin, tapered ends; move water through pits Vessel elements align end to end; form long micropipes called vessels Sugar-conducting cells of the phloem alive at functional maturity sugars transported in sieve tubes chains = sieve-tube elements (lack organelles; has a companion cell whose nucleus and ribosomes serve both cells) Sieve plates porous end walls; allow fluid to flow between cells. Concept 28.2: Meristems generate new cells for growth and control the developmental phases and life spans of plants indeterminate growth Can grow throughout lifetime; enabled by meristems (perpetually undifferentiated tissues) determinate growth plant organs cease to grow at a certain size Two main types of meristems Apical meristems Lateral meristems Apical meristems are located at the tips of roots and shoots and at the axillary buds of shoots elongate shoots and roots, a process called primary growth Lateral meristems add thickness to woody plants, a process called secondary growth Two lateral meristems: vascular cambium adds layers of vascular tissue called secondary xylem (wood) and secondary phloem cork cambium replaces the epidermis with periderm, which is thicker and tougher woody plants primary growth extends the shoots and secondary growth increases the diameter of previously formed parts Flowering plants can be classified by life cycle Annuals complete their life cycle in a year or less Biennials require two growing seasons Perennials live for many years Concept 29.6: The rate of transpiration is regulated by stomata Leaves broad surface areas; high surface-to-volume ratios; increase photosynthesis and water loss through stomata Guard cells balance water conservation with gas exchange for photosynthesis. About 95% of the water a plant loses escapes through stomata stoma surrounded by pair of guard cells; control the diameter of the stoma by changing shape. Mechanisms of Stomatal Opening and Closing Changes in turgor pressure open and close stomata turgid guard cells bow outward; pore opens flaccid guard cells less bowed; pore closes Changes in turgor pressure result from uptake and loss of potassium ions (K) by the guard cells Guard cells turgid/Stoma open Guard cells flaccid/Stoma closed H2O H2O H2O H2O K+ H2O H2O H2O H2O H2O H2O (b) Role of potassium ions (K+) in stomatal opening and closing Adaptations That Reduce Evaporative Water Loss Xerophytes plants adapted to arid climates Some desert plants complete their life cycle during the rainy season Others have leaf modifications that reduce the rate of transpiration Some plants use a specialized form of photosynthesis called crassulacean acid metabolism (CAM) where stomatal gas exchange occurs at night Concept 29.7: Sugars are transported from sources to sinks via the phloem Translocation transports sugars through phloem Phloem sap aqueous solution high in sucrose; travels from sugar source to a sugar sink. sugar source organ that is a net producer of sugar, e.g. mature leaves. sugar sink organ that is a net consumer or stores sugar, e.g. tuber or bulb Green dots are sugar. Loaded into sieve tube at source. Reduces water potential inside the sieve-tube elements causing the tube to take up water by osmosis. Water uptake generates positive pressure forcing sap to flow along a tube. The pressure is relieved by the unloading of sugar and the loss of water at the sink. In leaf-to-root translocation, xylem recycles water from sink to source.