Chapter 38

Transport of materials in plants 

 

 Root system absorbs water and dissolved minerals from the soil 

 Shoot system takes CO2 from the atmosphere via stomata 

 Photosynthetic cells use these materials to produce organic compounds needed for growth and reproduction 

 long-distance transportation occurs withing the plant body using a continuous system of conducting materials

 

 Xylem

 

 transport water and dissolved minerals 

 Only goes up 

 

 

 Phloem

 

 transports food and other solutes (hormones) 

 Goes up and down 

 

 

 

 

 

 

 Importance of water 

 

 Photosynthesis 

 support of plant organs 

 conduction 

 cell elongation 

 most chemical reactions 

 Average plant is 90% water 

 Solvent for most substances

 

 Solution

 

 Solvent 

 Solute 

 

 

 

 

 

 Properties of water 

 

 Polar molecule

 

 neutral 

 

 

 Hydrogen bonding 

 Cohesiveness 

 Adhesiveness 

 Temperature Stabilizer 

 Transport medium 

 Best biological solvent 

 Occurs in all 3 forms of matter within earth's temperature range 

 

 Principles of movement 

 

 Bulk\Mass flow

 

 Mass movement of liquid cause by pressure and\or gravity 

 Ex: leaching

 

 movement of ion though soil to plant roots 

 

 

 Faster than diffusion 

 

 

 Diffusion

 

 high concentration > low concentration 

 Simple diffusion

 

 Movement of molecules through a phospholipid bilayer down a concentration gradient 

 

 

 Facilitated  Diffusion

 

 transport of molecules across a plasma membrane down a concentration gradient with the aid of membrane protiens 

 

 

 

 

 Osmosis"gatekeeper"

 

 Diffusion across a selectively permeable membrane in response differences in solute concentration 

 simple diffusion of water does not occur rapidly enough for rapid expansion of plant cells 

 Aquaporins

 

 protein channels that allow facilitated diffusion of water 

 

 

 

 

 

 Tissue-level transport 

 

 trans-membrane transport

 

 export of material via membrane proteins, followed by import of the same substance by an adjacent cell 

 Ex. Auxin transport aided by carrier protiens 

 

 

 Symplastic Transport

 

 Movement from cytosol of one cell to cytosol of another cell via plasmodesmata

 

 Cytosol

 

 Everything inside the cell wall 

 

 

 

 

 

 

 Apoplastic transport

 

  movement along cell walls and inter-cellular spaces 

 Ex: water and disolved minerals 

 

 

 

 Cellular water content 

 

 water content of plant cells depends on osmosis, which depends on:

 

 Solute concentration 

 Turgor preassure

 

 hydrostatic pressure that increases as water enters plant cells 

 cell walls restrict the extent to which the cells can swell 

 

 

 

 

 

 

 

 

 

 Turgid plant cell has cytosol full of water and plasma membrane pushes up against the cell wall 

 Plasmolyzed cell has lost so much water that turgor pressure is lost and the plasma membrane no longer presses on the cell wall 

 

 

 

 Water potential 

 

 Potential energy of water 

 Water moves from highest to lowest water potential

 

 affected by

 

 pressure 

 solute concentration 

 other factors (damage, temperature) 

 

 

 

 

 Concept used in 2 ways

 

 to understand the movement of water into and out of cells (cellular water potential) 

 to understand the movement of water between entire plants and their enviroments 

 

 

 

 Water (and soil mineral) movement through the plant 

 

 Transpiration

 

 Evaporation of water from plant surfaces 

 "cost" for the plant to live on land 

 capable of pulling water up by bulk flow 

 primary form of long distance water transportation in plants 

 

 

 

 

 

 Stomata

 

 Opening has 2 guard cells

 

 control balance of CO2, O2, and H2O inside leaf 

 

 

 

 

 

 Xylem 

 

 Flowering plant xylem consists of 4 types of cells 

 

 

 Xylem parenchyma cells 

 Thick-walled supportive fibers

 

 may be alive or dead at maturity 

 

 

  vessel elements

 

 Speacilized water conducting cells and are always dead and empty of cytosol when mature 

 Wide tubes 

 

 

 Tracheids

 

 tracheory elements

 

 Rich in lignin which offers strength, durability, and water proofing 

 

 

 Narrow tubes 

 

 

 

 Stomata 

 

 Plants produce a waxy cuticle to prevent water loss 

 stomata facilitate gas exchange  

 90% of water that evaporates from plants is lost through stomata 

 when stomata are open, O2 and water vapor are released and CO2 is taken up 

 controlled by guard cell pairs 

 

 

 Mechanisms of Guard cells 

 

 Daytime/sunlight

 

 CO2 is low in leaf 

 

 

 Guard cells "pump" in K (potassium)

 

 Changes solute concentration 

 

 

 H2O from xylem moves by osmosis onto guard cells

 

 cells become turgid 

 

 

 Guard cells swell and open stomata

 

 CO2 diffusion into leaf 

 

 

 "Pump" out K (potassium)

 

 H2O moves out by osmosis out of guard cells causing shrinking 

 

 

 

   

 

 Pumping

 

 Expenditure of ATP energy 

 

 

 

 Causes of water loss 

 

 Sunlight energy

 

 heats up leaf causing evaporating of H2O from mesophyll cells 

 Causes a decrease in H2O concentration causing a "pull" of H2O 

 This "pull" moves H2O though the "Transpiration stream" 

 

 

 

 Transpiration Stream 

 

 Soil H2O (and nutrients) 

 root epidermis 

 root cortex 

 endodermis 

 root xylem 

 stem xylem 

 leaf xylem 

 mesophyll 

 Vapor into atmosphere 

 

 Unidirectional movement Only goes UP! 

 C-A-T Mechanism 

 

 Occurs once the stomata are open 

 Purely a physical process 

 "pull" of H2O one molecule at a time 

 unidirectional movement 

 
 C ohesion

 

 H2O molecules stick together 

 

 

   A dhesion

 

 H2O adheres to cellulose in cell walls 

 

 

 
 T ension

 

 "pull" due to H2O loss from mesophyll 

 

 

 NO ENERGY expended 

 Only energy is sunlight heating leaf 

 

 Solute movement in plants 

 

 Translocation

 

 movement of solutes in plants 

 

 

 food

 

 dissolved in H2O 

 Moved in form of Sucrose 

 

 

 Goes form Source to Sink

 

 Site with excess of carbohydrate 

 Site where the carbohydrate is stored or immediately needed 

 

 

 Bidirectional 

 

 Long-distance transport in phloem 

 

 Phloem transports sugars from where they are produced and\or stored to other sites where they are stored and/or needed

 

 Source > Sink 

 

 

 Primary Phloem

 

 Occurs in the vascular bundles of herbaceous plants 

 

 

 Secondary Phloem

 

 Occurs as the inner bark of woody plants  

 

 

 

 Phloem Structure 

 

 Phloem of flowering plants in composed of supporting fibers , parenchyma cells , sieve-tube elements , and adjacent companion cells (members) 
 

 Sieve-tube members (STM) are arranged end-to-end , and together with companion cells, form a system to transport soluble organic substances

 

 Sieve-tube members lose their nucleus and most of the cytoplasm to reduce obstruction to bulk flow 

 phloem sap passes through sieve plate pores 

 

 

 

 

 

   

 Pressure Flow Hypothesis 

 At source 

 

 Companion cells "pump" sucrose into STM (STP expended) 

 As sucrose concentration increases in STM, water potential (concentration) decreases within STM 

 Adjacent Xylem has higher water potential than STM, H2O moves into STM by osmosis 

 

 Bulk flow of Sucrose Higher Pressure > lower Pressure 

 At sink 

 

 Companion cells unload sucrose (ATP expended) 

 Sucrose converted into starch for storage in root cortex 

 Without sucrose, higher H2O potential in STM 

 H2O moves from STM to adjacent Xylem by osmosis 

 

 

 

 ATP spent only by companion cells at source (loading) and sink (unloading) 

 Bulk flow (pressure/potential differences) and osmosis (H2O potential\concentration differences)

 

 No energy Expended 

 

 

 

 Similarities Between Translocation and Transpiration 

 

 Both involve conduction 

 both involve physical properties of H2O 

 

 

 

 

 Translocation 

 Transpiration 

 

 

 

 

 Phloem 

 Bidirectional 

 Must expend ATP energy by plant 

 

 

 

 

 Xylem 

 Unidirectional 

 Sunlight energy (no expenditure by plant)