Transport across boundaries Learning Outcomes explain what is
Transport across boundaries
Learning Outcomes • explain what is meant by passive transport (diffusion and facilitated diffusion including the role of membrane proteins), active transport, endocytosis and exocytosis;
Learning Outcomes • explain what is meant by passive transport (diffusion and facilitated diffusion including the role of membrane proteins), active transport, endocytosis and exocytosis;
Exchange across the plasma membrane • The membrane provides an effective barrier against the movement of substances, however some exchange between the cell and the environment is essential.
Transport across membranes • Materials can move across cell membranes: – Passively • Diffusion (simple or facilitated) • Osmosis – Actively • Active transport • Bulk transport
Diffusion • Net movement of molecules or ions from a region of high concentration to a region of low concentration • Occurs along a concentration gradient • Result = equilibrium (molecules or ions evenly spread out within a given space or volume)
Factors affecting the rate of diffusion • Concentration gradient – Greater the difference in concentration the greater the rate of diffusion • Temperature – At higher temperature kinetic energy particles increases – Diffusion is faster • Surface area – Greater the surface area, more particles can cross – Increases rate of diffusion
Factors affecting the rate of diffusion • Nature of molecules or ions – Large molecules diffuse slower – Non-polar molecules diffuse more easily – The respiratory gases (CO 2 and O 2) are small enough to diffuse quickly through the membrane. – Large, polar molecules (glucose and amino acids) and ions (Na+ and Cl-) cannot diffuse through the phospholipid bilayer
Facilitated Diffusion • Protein molecules exist in membranes to facilitate diffusion. • 2 type of protein molecule – Channel protein • transmembrane protein that forms a tunnel through the bilayer. – Carrier proteins • change shape to help molecules move into and out of cells.
Facilitated Diffusion
Active Transport • Energy consuming transport of molecules or ions across a membrane against a concentration gradient, made possible by transferring energy from respiration. • Energy makes the carrier proteins change shape, transferring ions across the membrane.
Examples of active transport • Reabsorption in kidneys • Digestion in gut – Helps absorb glucose from our intestines • Load sugars into phloem • Inorganic ion uptake in root hairs – Magnesium ions are in short supply in the soil but are needed for photosynthesis
Bulk transport • This is the method of transporting large quantities of materials into cells (endocytosis) or out of cells (exocytosis) – Endocytosis - Engulfing of material by cell membrane to form a endocytic vacuole. • 2 forms – Phagocytosis the uptake of solid material – Pinocytosis the uptake of liquid – Exocytosis - Process by which materials are removed from cells
Examples of bulk transport • Hormones released into bloodstream from endocrine glands • White blood cells engulf invading microorganisms by phagocytosis • In plant cells materials to build the cell wall are carried outside in vesicles.
OSMOSIS • Special type of diffusion involving water molecules • Example: – Two solutions are separated by a partially permeable membrane. Solute molecules are too large to pass through pores in the membrane, but water molecules are small enough.
What would happen if the membrane were not present?
• Net movement of solute molecules from B to A by diffusion • Net movement of water molecules from A to B by diffusion • Equilibrium – concentrations of water molecules and solute molecules in A would equal that in B.
What will happen if the membrane is present?
What will happen if the membrane is present?
• Solute molecules too large to pass through membrane • Water molecules pass easily from A to B • Net movement of water from A to B until equilibrium is reached, i. e. solution A has the same concentration of water molecules as solution B. • The level of liquid A will fall and the level of liquid B will rise • Equilibrium is brought about by the movement of water molecules alone.
Definition of osmosis • Water potential Ψ – Tendency of water molecules to diffuse from one place to another. – Measured in k. Pa – Pure water has a water potential of 0 k. Pa • Osmosis – Is the net movement of water molecules from a region of high water potential to a region of low water potential (down a water potential gradient) across a partially permeable membrane.
Water potential Pure water No solute Lower water potential -50 k. Pa Dilute solution Small amount of solute dissolved Very low water potential -500 k. Pa Concentrated solution Large amount of solute dissolved Decreasing water potential Highest water potential 0 k. Pa
Some Important Terms • Hypotonic – a region of • higher water potential. • Lower solute concentration • Hypertonic – a region of • lower water potential • Higher solute concentration • Isotonic – a region where there are equal water potentials on either side of a membrane.
Determining Water Potential in Potato tubers Salt Soluntion (mol-1) 0. 1 0. 2 0. 3 0. 4 0. 5 Starting Mass (g) Finishing mass (g) Change in mass (g) %age change in mass
Osmosis in Red Blood Cells
Osmosis in Plant Cells
Important Terms • Turgid – the term used to describe a plant cell where the protoplast exerts a pressure on the cell wall. • Plasmolysed – the term used to describe a plant cell where the protoplast has shrunk away from the cell wall due to loss of water by osmosis.
Osmosis in red onion cells
Cell Division, Cell Diversity and Cellular Organisation OCR AS Biology Unit F 211: Cells, exchange and transport Module 1: Cells
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