Chapter 23 Plant Structure and Function Section 23
- Slides: 60
Chapter 23 Plant Structure and Function
Section 23 -1 Specialized Tissues in Plants
Structure of a Seed Plant 3 organs -> roots, stems, leaves Linked by tissues that provide support, protection, nutrient production and transport
Structure of a Seed Plant Roots Anchor plants, prevent erosion, absorb nutrients/water and transport them, store food, hold plants upright Stems Produce leaves/reproductive structures, contain transport systems Leaves Photosynthesis, have adjustable pores to reduce water loss and help gas exchange
Plant Tissue Systems 3 main tissue systems -> dermal, vascular, and ground Dermal Tissue - protective, outer covering Single cell layer in young plants called epidermis, the outer surface often covered with a waxy cuticle In older plants usually many layers, sometimes covered with bark Some epidermal cells have trichomes, which protect leaves and give them a fuzzy appearance In roots, incudes root hairs to absorb water
Plant Tissue Systems Vascular Tissues – support plant bodies, transport water and nutrients Xylem – transports water Phloem – transports products of photosynthesis
Xylem Cells called tracheids As they mature, they die and leave their cell walls which contain lignin (gives wood strength) Cells have connecting openings for water to pass Pits allow water to diffuse into ground tissue
Xylem Angiosperms have second xylem tissue called vessel elements – wider than tracheids, arranged end to end Mature and die, cell walls develop slits at each end for water to move freely
Phloem Alive at maturity Main cells called sieve tube elements, arranged end to end forming sieve tubes Small holes at ends so nutrients can move from cell to cell Lose nuclei and most organelles as they mature
Phloem Companion cells surround sieve tube elements - keep nuclei/organelles
Plant Tissue Systems Ground tissue – produces/stores sugars, contributes to physical support Parenchyma cells – thin walls, large central vacuole surrounded by thin layer of cytoplasm – chloroplasts in leaves Collenchyma cells – thicker walls, flexible, provide support Sclerenchyma cells - thickest walls, rigid, makes up seed coat
Parenchyma Collenchyma Sclerenchyma
Plant Growth and Meristems – regions of unspecialized cells in which mitosis produces new cells ready for differentiation Apical meristems found in places of rapid division – tips of stems and roots
Plant Growth and Meristems At first, cells produced in apical meristems are all thin, unspecialized Gradually mature and differentiate to form each tissue system Meristems also create highly specialized cells of cones and flowers Patterns of gene expression changes the stem’s apical meristem
Section 23 -2 Roots
Root Structure and Growth As soon as a seed sprouts, its first root brings in water/nutrients from soil Cells divide rapidly, pushing root tips into soil, providing raw materials for developing stems and leaves
Root Structure and Growth Taproot Systems Primary root grows long and thick (taproot) giving rise to smaller branches Can store sugars and starches Fibrous Begin Root Systems with one primary root, which is replaced by many equally sized branches that grow separately from the base of the stem Help prevent soil erosion
Dandelion (taproot) Grass (fibrous root)
Anatomy of a Root Epidermis made of dermal tissue – protection and absorption Surface covered in root hairs – penetrate between soil particles and increase surface area Cortex composed of ground tissue Water/minerals move from epidermis Stores products of photosynthesis and starches
Anatomy of a Root Endodermis – layer of ground tissue enclosing vascular cylinder – moves water and minerals to center of root Vascular cylinder in the center composed of xylem and phloem Dicot roots have central column of xylem
Anatomy of a Root Apical meristems near root tip allow roots to increase in length Root cap protects meristem, secretes slippery substance to ease progress through soil Cells at tip scraped away and replaced continually
Root Functions Uptake Soil of plant nutrients contains sand, silt, clay, air, bits of decaying animal/plant tissue in varying amounts Plants need inorganic nutrients like nitrogen, phosphorus, potassium, magnesium, calcium Trace elements also important, but excessive amounts can be toxic
Root Functions Active transport of dissolved nutrients Active transport proteins in root hairs, other epidermal cells Bring in mineral ions from soil Water movement by osmosis Mineral ions accumulate in root, water “follows”
Root Functions Movement Move into vascular cylinder through cortex Cylinder enclosed by endodermis – cells meet and cell walls from waterproof zone called Casparian strip forces water/minerals to move through cell membrane rather than between cells – filter and control water Ensures one-way flow
Root Functions Root pressure Minerals pumped into vascular cylinder, water follows by osmosis creating pressure Water has to go up - root pressure forces water through vascular cylinder into the xylem Up and up!
Section 23 -3 Stems
Stem Function Produce leaves, branches and flowers Hold leaves up to sun Transport substances Xylem and phloem form continuous tubes from roots to stems to leaves In many plants they function in storage and aid in photosynthesis
Anatomy of a Stem Surrounded by layer of epidermal cells with thick cell walls and a waxy protective coating
Anatomy of a Stem Growing stems have nodes where leaves are attached Buds contain apical meristems to produce new stems and leaves Larger plants have woody stems to support leaves and flowers
Monocot Stems Vascular bundles (clusters of xylem and phloem) scattered throughout ground tissue composed mainly of parenchyma cells
Dicot Stems Vascular bundles arranged in a ring pattern Parenchyma cells inside ring called pith, outside form cortex Complexity increases as stem increases in diameter
Primary Growth Occurs in all seed plants – apical meristems increase plant length
Secondary Growth Larger plants require older parts of stem to increase in thickness Common in dicots and gymnosperms
Secondary Growth Takes place in meristems called vascular cambium (produced vascular tissues, increase thickness of stem) and cork cambium (outer covering)
Growth from Vascular Cambium Thin layer of cells between xylem and phloem Xylem pushed in, phloem pushed out Increases diameter of stem each year
Wood Formation Layers of secondary xylem produces by vascular cambium Older xylem near center no longer carries water – heartwood (dark) Surrounded by sapwood – active in fluid transport (light)
Tree Rings In spring, vascular cambium produces light colored rings of xylem (early wood) Cells grow less as season continues, have thicker cells walls, darker in color (late wood) A ring = a year of growth Thick rings mean favorable weather
Formation of Bark Everything outside the vascular cambium in a mature stem (phloem, cork cambium, cork) Expansion leads to oldest tissue splitting Cork cambium surrounds cortex producing a thick layer of cork to prevent water loss Outer layers may flake off as stem thickens
Section 23 -4 Leaves
Anatomy of a Leaf Blade – thin, flat part of leaf – maximum light absorption Blade attached to stem by petiole Outer covering of dermal tissue Top and bottom covered by epidermis, tough irregular cells with thick outer walls Covered by waxy cuticle – waterproof, prevents water loss
Anatomy of a Leaf Vascular tissues bundles into veins that run from stem through leaf Palisade mesophyll beneath upper epidermis – closely packed cells that absorb sunlight Spongy mesophyll contains air spaces connected to stomata – small opening in epidermis allowing for gas exchange
Transpiration Mesophyll cell walls moist for easy diffusion Water can evaporate from these surfaces by transpiration May be replaced by water from xylem Cools leaves on hot days, but can threaten survival
Gas Exchange gases between air spaces in spongy mesophyll and exterior by opening stomata
Homeostasis If stomata were always open, too much water would be lost to transpiration Open just enough to allow photosynthesis Guard cells control opening and closing of stomata, regulating movement of gases
Homeostasis When water is abundant, increaser in water pressure in guard cells opens stoma by curving When water is scarce, water pressure in guard cells drops and stoma closes Stomata usually open during day, closed at night Can be closed in bright sunlight or hot/dry conditions Respond to environment
Transpiration and Wilting Osmotic pressure keeps leaves/stems rigid Water loss due to transpiration can lead to a loss of pressure in the cells
Adaptations of Leaves Pitcher plant – attract/digest insects to obtain nitrogen Living stone (rock plant) – 2 leaves for hot/dry conditions are round to minimize exposure to air, have very few stomata Spruce – waxy epidermis, stomata sunken below leaf surface Cactus – photosynthesis occurs in stems, leaves are thorns
Section 23 -5 Transport in Plants
Water Transport Combination of transpiration and capillary action moves water through xylem Water evaporates through stomata, leaf dries out, water is pulled up through xylem
How Cell Walls Pull Water Upward Water molecules attracted to each other by cohesion – H bonds form between molecules Water molecules bond to other substances by adhesion
How Cell Walls Pull Water Upward Capillary action is the tendency of water to rise in a thin tube because of cohesion and adhesion Thinner tube, higher water will rise
Putting it All Together Xylem tissue hollow, connected tubes (tracheids and vessel elements Tubes are lined with cellulose cell walls (adhesion) Transpiration removes water from the exposed walls, adhesion pulls water from interior of leaf Pull is powerful - extends down through tips of roots to the water in the soil
Nutrient Transport Pressure-flow 1. 2. 3. hypothesis Membranes of sieve tube cells use active transport to move sugars from cytoplasm into sieve tube itself Water follows by osmosis, creating pressure at the source of the sugars If a plant region has a need for sugars, they are actively pumped out of the tube and into the tissue water leaves the tube via osmosis, reducing the pressure
Nutrient Transport Flow of nutrient-rich fluid from the sources of sugars (source cells) to the places where sugars are used or stored (sink cells) Flexibility in changing seasons
- Chapter 22 plant structure and function answer key
- Chapter 21 plant structure and function
- Section 23-4 leaves
- Chapter 7 cell structure and function section review 7-2
- Animal vs plant cell venn diagram
- Chapter 21 section 1 plant evolution and adaptations
- Anthocerophytes
- Chapter 35 plant structure growth and development
- Primary growth and secondary growth in plants
- Chapter 7 section 4 cellular transport
- Tronsmo plant pathology and plant diseases download
- Tronsmo plant pathology and plant diseases download
- Albugo eye
- Scope of plant breeding
- Plant breeding for disease resistance
- Plant introduction in plant breeding
- Chapter 10 body structure and function
- Biology chapter 7 cell structure and function
- Chapter 5 cell structure and function
- Chapter 7 membrane structure and function
- Chapter 5 the structure and function of macromolecules
- Chapter 7 membrane structure and function
- Chapter 7 membrane structure and function
- Chapter 7 membrane structure and function
- Chapter 10 section 1: meiosis
- Aerial parts of plants
- Plant structure growth and development
- Chapter 4 section 2 the structure of atoms
- Struktur organisasi laundry department
- School community definition
- Shoot system in plants
- Parts of a plant foldable
- Parts of the plants and their functions
- Functions of the parts of a seed
- Function of plant leaf
- What is the function of cell wall in plant cell
- What is the main function of xylem within a plant brainpop
- Mitochondria house analogy
- Nucleolus gif
- Function of stems
- Structure of leaf
- Full sectional drawing
- Section 2 describing energy worksheet answers
- Chapter 25 plant responses and adaptations
- Positive geotropism
- Chapter 10 property plant and equipment
- Chapter 9 plant and intangible assets
- Seed germination
- Plant and intangible assets chapter 9
- What produces pollen in a flower
- Strawberry placentation
- Plant structure drawing
- Structure
- Plant cell structure under electron microscope
- Cutin
- Stoma function
- Plant structure gcse
- Moss plant structure
- Phytomere
- Plant cell
- Ultra structure of plant cell