Bio 2 4 Cell Processes Active Transport Passive
Bio 2. 4 - Cell Processes Active Transport Passive Transport SA: V Ratio
Links • Active & Passive Transport Animations http: //www. northland. cc. mn. us/biology/biol ogy 1111/animations/transport 1. swf • Transport Videos http: //www. linkpublishing. com/videotransport. htm#Blood_-_Isotonic_Solution •
Passive Transport • Movement of a substance (eg oxygen) from an area of high concentration to an area of low concentration across a *selectively permeable membrane. • Passive = no energy (ATP) used *allow small polar molecules through including some water (water is polar) but not large molecules (eg protein, glucose). Mostly it is dissolved gases and lipid soluble molecules that pass through.
• Factors affecting rate – Conc gradient: diffusion rate higher when greater difference in concentrations – Diffusion distance: faster over shorter distances – Surface area: larger the area for diffusion the faster the diffusion rate – Temperature: molecules move faster at higher temperatures (up to a point in living systems) – Size of molecule: larger molecules diffuse slower – State of matter: gases > liquids
• Types of passive transport – Simple (directly across membrane), – Osmosis (water only), – Facilitated diffusion: • protein carriers / cannels assist the passage of certain molecules especially large molecules (glucose) and lipid insoluble molecules. • this speeds up the rate of diffusion of these molecules. • water, oxygen and glucose enter cells through facilitated diffusion
Net Diffusion
Equilibrium
Osmosis • Diffusion of WATER – Across a selectively permeable membrane • Water moves from [high water] [low water] – Or “water moves from lower to higher solute conc” – Think: “salt sucks”
Q What will happen?
Question Which way will water travel across a semi-permeable membrane between 2 solutions of 5% and 20% dissolved starch?
Answer Which way will water travel across a semi-permeable membrane between 2 solutions of 5% and 20% dissolved starch? 98% water 95% water Water (moves down gradient) Water moves from an area of high concentration to an area of low concentration, across the selectively permeable membrane Net diffusion occurs until equilibrium is reached (isotonicity), or water pressure pushes back or the cell bursts…
Types of Solutions • • Isotonic (iso – “same”) Solute concentration equal both sides No net movement of water (cell in equilibrium) Plant cells flaccid (contain water but not swollen with it) • • • Hypotonic (hypo = “less”) Less solute outside of cell Net movement of water into cell (high water to low water concs) Plants: vacuole fills, cells turgid, cell wall prevents lysis (bursting) Animals: cell swells, may burst If in doubt remember: L • • • Ow SOlute = Hyp. O Hypertonic (hyper = “more”) More solutes outside of cell Net movement of water out of cell(high water to low water concs) Plants: vacuole empties, cells shrivel, plant wilts (cells plasmolysed – cell membrane may detach from wall), may die Animals: cell shrivels, may die
Cells in different solutions
Cells in different solutions
Use your knowledge of osmosis to explain: 1 Your mouth feels dry after eating chips 2 You can’t drink seawater 3 Retreating soldiers salt the fields of their enemies 4 Salt is able to preserve food 5 You gargle salt water for a sore throat 6 My dad used to put salt on thistles to kill them 7 Sea turtles have salty tears 8 You chop up tamarillos and sprinkle them with sugar, later there is juice all around the fruit 9 The bitter taste of eggplant (aubergine) can be removed by sprinkling the chopped up food with salt.
Active Transport • Movement of substances from an area of low concentration to an area of high concentration, across a selectively permeable membrane. Eg plant root cells absorb nitrate from soil (low conc) into cells (high conc). • Requires energy (ATP) • Includes movement of molecules too large to move across the membrane (eg glucose) • Types: – Ion Pumps – Endocystosis • Phagosytosis • Pinocytosis – Exocystosis
Cytosis Endocytosis The process by which large substances (or bulk amounts of smaller substances) enter the cell without travelling across the plasma membrane An invagination of the membrane forms a flask-like depression which envelopes the material; the invagination is then sealed off forming a vesicle There are two main types of endocytosis: 1. Phagocytosis The process by which solid substances (e. g. food particles, foreign pathogens) are ingested (usually to be transported to the lysosome for break down) 2. Pinocytosis The process by which liquids / solutions (e. g. dissolved substances) are ingested by the cell (allows quick entry for large amounts of substance) Exocytosis The process by which large substances exit the cell without travelling across the plasma membrane Vesicles (usually derived from the golgi) fuse with the plasma membrane expelling their contents into the extracellular environment
Exocytosis
Compare Active and Passive Forms of Transport
Compare Active and Passive Forms of Transport Passive Transport Active Transport • does not require energy • requires energy (ATP) • across membrane or facilitated by proteins • only occurs through proteins (ion pumps), budding of membrane • travels down concentration gradient High concentration Passive transport (diffusion) Low concentration • travels against concentration gradient High concentration Active transport Low concentration
Passive Transport Active Transport What types of molecules? • Small ones Eg: • Large ones • Salts • Dissolved gases (O 2, CO 2) • Ions • Water (osmosis) • Glucose (fac. Diff) • NOT starch, sucrose • Where transport against the conc gradient is required: • Excretion of Na+ ions from the gills of salt water fish • Ones where the conc. is low in the environment but the cell needs it at a higher conc. Eg: • Reabsorption of all glucose back into blood from kidney tubules • Uptake of nitrates by root hairs
The Size of Cells tend to be small ie <100 um (0. 1 mm) Why? By small I mean in volume (motor neurons in humans may be long - up to 1. 3 m long but are thin, so have a low volume)
Importance of Surface Area to Volume Ratio is a factor affecting cell size • • • The rate of metabolism of a cell is a function of its mass / volume The rate of material diffused in and out of a cell is a function of its surface area As the cell grows, volume increases faster than surface area (leading to a decreased SA: Vol ratio) If the metabolic rate is greater than the rate of exchange of vital materials and wastes, the cell will eventually die Hence the cell must consequently divide in order to restore a viable SA: Vol ratio and survive Cells and tissues specialised for gas or material exchange (e. g. alveoli, cells lining small intestine) will increase their surface area to optimise the transfer of materials by having structures such as a flattened shape, hairs, villi.
SA: V Ratio As the cells below grow the volume increases at a faster rate than surface area so the SA: V ratio decreases and the rate of diffusion will be insufficient to keep the cell alive.
Still confused about cell size and scale? Go here: http: //learn. genetics. utah. edu/content/cells/scale/
Something Interesting • http: //vcebiology. blogspot. co. nz/2012/08/why-arecells-so-small-surface-area-to. html
- Slides: 29