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http://www.csdl.tamu.edu/FLORA/hdwimages1/ UNIT III: PLANT FORM AND FUNCTION •Plant structure and growth •Plant nutrition •Plant reproduction and development Cardinal Flower Arabidopsis thaliana Red Maple Purves et al 2000 Purves et al 2000 Evolutionary relationships among the Angiosperms. The monocots and eudicots are the largest monophyletic groups among the angiosperms. (The “other groups” remain to be placed accurately on the phylogenetic tree). Monocotylenous and Dicotyledonous Plants •Monocots • ~65,000 species • Lilies, irises, orchids, cattails, all the grasses and grains… •Monocot lineage, taxon, is monophyletic; evolved from dicot ancestor •Dicots •~175,000 species • Most trees and shrubs • Most annual plants – mints, sunflowers, peas, snapdragons •Most dicots are in members of the Eudicot lineage – a monophyletic taxon Palms Grasses Lilies Purves et al 2000 Examples of Monocot angiosperms Purves et al 2000 Cactus Flowering Dogwood Rose Examples of Dicots (more specifically, Eudicots) Source: Freeman (2002) Phylogenetic relationships among Angiosperm lineages Angiosperms Oldest living Non-Angiosperms angiosperm lineages Lineages in green are traditionally called dicots - the seeds of these lineages have two “seed leaves”. “Dicots” don’t form a monophyletic group -- ie monocots are descended from a “dicot” lineage “Eudicots” are a monophyletic group that includes much of the angiosperm diversity Several lineages related to magnolias Monocots Eudicots Phylogenetic relationships of the orders of flowering plants (AGP, 1998) •Monocots apparently diverged from dicots early in the history of the phylum http://www.csdl.tamu.edu/FLORA/newgate/cronang.htm ANNUAL, BIENNIAL AND PERRENIAL PLANTS Annual Plants Life cycle (vegetative growth and reproduction) occurs in the course of a single year; die after single year of growth. Most are entirely herbaceous, ie, lack secondary growth, secondary tissue (wood); some (eg sunflowers) produce poorly developed secondary tissues. Many crop plants (incl. corn, wheat, soybeans) are annuals. Desert annuals (above) and a giant redwood (below) Biennial Plants Narrow definition; life cycle takes two years to complete. Generally, vegetative growth in the first year; flowering and senescence in the second year. Many “bienniels” flower in year 3 or later, but all flower only once before dying. Much less common than annuals. Crop plants include carrots, cabbage. Wild plants include evening primrose, queen anne’s lace Perennial Plants Life cycle extends for for multiple, often many years; flower repeatedly and live for many years. Most vascular plants are perennials. Many are herbaceous plants (eg wildflowers of prairie, wetlands and woodlands) that usually lack secondary growth in stems; stems die back each year following food accumulation, often in substantial roots Trees and shrubs have secondary growth and are perennial, they are either deciduous (shed leaves at particular time of year) or evergreen (leaves drop throughout year, plant never appears leafless) Sources: Raven & Johnson 1999, Purves 2000) PLANT STRUCTURE AND GROWTH The Angiosperm Body •root and shoot systems; adaptations to terrestrial life •structural adaptations of protoplasts and cell walls; specialized functions •plant tissue systems; dermal, vascular and ground Plant Growth •meristems continuously generate cells for new organs •Primary growth; apical meristems •(Secondary growth: lateral meristems) BASIC ORGANIZATION OF PLANT BODY; ADAPTATION TO TERRESTRIAL LIFE Root system; anchor; absorption & transport of water, ions, dissolved mineral nutrients; food storage •Shoot system; stem is scaffold for photosynthetic leaves and reproductive structures; transport of sugars from photostynthetic to non-photosynthetic parts of plant Solomon et al 1999 Campbell et al 1999 Shoot Root Roots Shoots Biological Organization in Plants Cells Plant cells are eukaryotic, with some unique modifiations, including the cell wall. Cell types include Parenchyma, Collenchyma Schlerenchyma, Tissues Tissues plant cells are organized into tissues; groups of cells that form a structural and functional unit. Simple plant tissues consist of single cell type. Complex plant tissues consist of two or more kinds of cells. Shoot Tissue systems Groups of tissues that extend throughout plant body; Three main tissue sytems; ground, vascular, dermal Organs Roots, stems. leaves, flower parts, and fruits are referred to as organs because each is composed of several different tissues. The tissue systems of different plant organs fornm an interconnected network througout the plant. Root CELL SPECIALIZATION; STRUCTURAL ADAPTATION IN CELL WALLS AND CELL PROTOPLAST* In plant cell division, daughter cells secrete a “middle lamella” that will adhere the adjoining cells Each the secretes a primary cell wall of cellulose and other polysaccharides, which grows with growing cell Depending on cell specialization, after growth to final size, cell may lay down a secondary cell wall of polysaccarides and, depending on cell type, lignin (characteristic of wood) or suberin (characteristic of cork, bark) Secondary cell walls typically function in structural support or waterproofing *Protoplast: cell contents exclusive of cell wall Purves et. al. 2000 CELL SPECIALIZATION; STRUCTURAL ADAPTATION IN CELL WALLS AND CELL PROTOPLAST In addition to other features of Eukaryotic cells, plant cells have: •cell wall •chloroplasts •central vacuole, Raven & Johnson 1999 Cell plate formation between two nuclei, during plant cytokinesis Raven and Johnson 1999 PLANT CELLS ARE ORGANIZED INTO TISSUE SYSTEMS Plant organs have three tissue systems that are continuous throughout the plant body. The tissue systems derive from meristem tissue; localized regions of cell division •Meristems; apical & lateral meristems give rise to all cells and tissues •Ground tissue system; storage, secretion, photosynthesis; mostly parenchyma cells •Vascular tissue system; conduct water & minerals (xylem), & carbohydrates, amino acids, hormones… (phloem) •Dermal tissue system; outer protective covering *We will discuss specialized reproductive tissue in a later lecture THE THREE TYPES OF CELLS AND GROUND TISSUES IN PLANTS Parenchyma Collenchyma • Parenchyma cells are relatively unspecialized; large vacuoles, thin primary wall (no secondary) •Collenchyma cells provide support to growing stems and leaves; thickened primary cell walls • most common type of plant cell; responsible for most of plant metabolic functions primary sites of photosynthesis, starch storage…. •Relatively flexible, allowing organs to bend without breaking Sclerenchyma •Sclerenchyma cells have tough, thick secondary walls, often impregnated with lignin •Two types specialized for support; fibers and sclereids. Both function to strengthen tissue in which they occur •Fleshy tissue of most fruits (Solomon et al 1999) cross-section from grass blade cross-section of a young elderberry branch cluster of sclereids (stained red) in pulp of pear Raven and Johnson 1999 Vascular tissue functions in the movement of water, dissolved inorganic materials and carbohydrates through a plant Cell Types in Vascular Tissue System Xylem cells •Tracheids & vessel elements; both function in water transport; both modified sclerenchyma cells •Both have secondary cell walls and are dead at functional maturity •Dual function in gymnosperms; water transport, structural support (structural support in angiosperms provided mainly by fiber cells Tracheids Vessel Elements •long, thin cells with tapered ends •usually wide, short, oblique ends, thinwalled, compared to tracheids •water moves between cells across pits •function in support; secondary walls hardened with lignin •perforated end walls facilitates water flow VESSEL ELEMENT Photomicrograph shows longitudinal section of two vessel elements from an unknown woody dicot Solomon et al 1999 longitudinal section transverse section Phloem Cells •Sieve-tube members: Food-conducting cells, arranged end to end with porous walls (sieve plates) between them; cells living at functional maturity, but lacking nuclei, ribosomes •Companion cells: Nucleated companion cell lies along side each sieve-tube member SELECTED CELL TYPES OF THE PLANT DERMAL TISSUE SYSTEM Epidermal Cell; •living parenchyma cell with thin primary wall •outer wall usually thickened and covered by an extra-cellular waxy cuticle •reduces water loss & protects surface of plant body •epidermis is usually one cell layer thick Guard Cell •specialized epidermal cells on leaves that function in pairs; stoma (pore) is a gap between two guard cells •guard cells, stoma, regulate gas exchange and water loss (transpiration) solomon et al 1999 PLANT GROWTH Meristems generate cells for new organs throughout the lifetime of a plant •Primary plant growth; -Apical meristems extend roots and shoots by giving rise to the primary plant body •Secondary plant growth: -Lateral meristems add girth by producing secondary vascular tissue and periderm Apical and Lateral Meristems Apical meristems produces primary plant body; lateral meristems produce the secondary plant body Raven and Johnson 1999 Vascular tissue functions in the movement of water, dissolved inorganic materials and carbohydrates through a plant