1 / 36

MOVEMENT THROUGH THE MEMBRANE Bubble Lab

MOVEMENT THROUGH THE MEMBRANE Bubble Lab. Section 7-3. The cell membrane. Function : Regulates what enters and leaves the cell. Provides protection and support Selective permeability Some substances can pass across the cell membrane and others can’t. Structure.

Download Presentation

MOVEMENT THROUGH THE MEMBRANE Bubble Lab

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. MOVEMENT THROUGH THE MEMBRANEBubble Lab Section 7-3

  2. The cell membrane • Function: Regulates what enters and leaves the cell. Provides protection and support • Selective permeability Some substances can pass across the cell membrane and others can’t

  3. Structure Phospholipid Bilayer (Fluid Mosaic Model): a double-layer sheet that makes up cell membranes.

  4. Components of the lipid bilayer • Polar Head • Hydrophilic “Water Loving” • Lipid Tails • Hydrophobic “Water Fearing”

  5. Why is the lipid bilayer important? • Tough, flexible structure • Strong barrier between the cell and its environment

  6. What does it do for the cell? • Allows only certain materials to pass in and out at certain times. Ex. Ions (Na+, K+, Cl-) polar (hard to pass) Glucose – large and polar (hard to pass) Water – polar (hard to pass) Oxygen – small nonpolar (easy to pass) Carbon dioxide – small nonpolar (easy to pass)

  7. Other membrane structures • Protein molecules • Form channels and pumps that help to move material across the membrane

  8. Other Membrane Structures • Carbohydrate molecules • Act like ID markers for the cell • Basis for blood typing: the antigens on the blood cells (A, B, AB) are carbohydrate chains

  9. Diffusion Definition: The movement of molecules from an area of higher concentration to an area of lower concentration, until equilibrium is reached. Equilibrium – concentrations of molecules are the same in all areas Diffusion of Molecules

  10. What causes diffusion? • Diffusion is caused by the constant movement and collision of molecules. More molecules = More collision • The collisions cause the molecules to spread out.

  11. Diffusion in Cells Molecules are able to diffuse through the cell membrane and allow the cell to function. Facilitated Diffusion – some molecules need help from protein channels to cross the cell membrane. Animation

  12. Osmosis (A special kind of diffusion) Osmosis is the diffusion of water molecules through a selectively permeable membrane. Selectively permeable? only certain substances can pass through the membrane Selectively Permeable - Osmosis

  13. Osmosis Isotonic – concentration of solute is the same on both sides of the membrane (equilibrium) Hypertonic – the solution with a higher concentration of solute Hypotonic – the solution with a lower concentration of solute

  14. Osmosis Practice The cytoplasm of Elodea cells is composed of about 70% water molecules and 30% other kinds of molecules. What happens when the Elodea cells are put into a liquid that is a. 50 percent water. b. 70 percent water. c. 100 percent water .

  15. Passive Transport Moving down a concentration gradient is like riding a bike down a hill. It doesn’t require energy, goes high to low. Osmosis, diffusion and facilitated diffusion are examples of passive transport! ACTIVE TRANSPORT Moving up a concentration gradient is like riding up a hill. IT REQUIRES ENERGY (ATP).

  16. Active Transport • Active Transport: is the movement of materials through a cell membrane using energy. • Molecules move from low concentration to high concentration. • Protein pumps use ATP to pump ions and small molecules against concentration gradient.

  17. Other types of Active Transport • Endocytosis – the process of taking material into the cell by means of infoldings of the cell membrane. • Phagocytosis – extension of the cytoplasm surround and engulf the particle • Pinocytosis – similar to phagocytosis, but cells take up liquid instead of particles.

  18. Types of Active Transport 2. Exocytosis • Large molecules move from inside the cell to outside the cell. • Contractile Vacoule – an organelle that constantly pumps H2O out of the cell. Animation

  19. 7.4 Specialized Cells • Cells with a specific structure and function and are found in multi-celled organisms. • We have blood cells, brain cells, bone cells, liver cell, skin cells, etc.

  20. We are all made of cells Organ System Organs Tissues Cells

  21. Tissue • Definition: A group of similar cells working together. • Examples

  22. Organs • Definition: A groups of tissues working together to perform a specific job.

  23. Organ Systems • Definition: Many organs working together to do a specific job.

  24. 7.3-7.4 Wrap up Questions • Explain Diffusion • Explain Osmosis • What does selectively permeable mean? • What is facilitated diffusion? • Are phospholipids the only molecules in a cell membrane? • What is active transport? • What are tissues, organs, and organ systems? Give Examples

  25. = cell 10% salt 10% salt 20% salt 10% salt 10% salt 20% salt Label the environment around the cell in each beaker as hypertonic, hypotonic or isotonic. Label the net flow of water and state what will happen to the cell in each beaker?

  26. = cell 10% salt 10% salt 20% salt 10% salt 10% salt 20% salt Label the environment around the cell in each beaker as hypertonic, hypotonic or isotonic. Label the net flow of water and state what will happen to the cell in each beaker? = cell 10% salt 10% salt 20% salt 10% salt 10% salt 20% salt Label the environment around the cell in each beaker as hypertonic, hypotonic or isotonic. Label the net flow of water and state what will happen to the cell in each beaker?

  27. Cell membrane reading questions • Compare and contrast integral and peripheral proteins. Integral proteins span the width of the membrane, some have a hydrophilic channel (channel protein) to transport hydrophilic substances into or out of the cell. Peripheral proteins are really appendages bound to the surface of the membrane that tie into the cytoskeleton and provide support.

  28. Cell membrane reading questions 2. What are the differences between the two types of transport proteins discussed in the article (use figure 7.10 to help you) One type has a hydrophilic channel selective for a particular solute. The second shuttles a substance from one side to the other by changing shape (carrier proteins and protein pumps) Some use ATP as an energy source

  29. Cell membrane reading questions 3. Why are proteins so essential to keeping your cells hydrated? The aquaporin is a channel protein that tremendously increase the rate at which water can enter the cell (3 billion per second)

  30. Cell membrane reading questions 4. Explain how diffusion relates to a concentration gradient. Molecules spread out evenly into available space. Each moves randomly, but directional from high to low concentration gradient (“down” the concentration gradient)

  31. Cell Membrane Structure

  32. Cell Membrane Diagram (phospholipid bilayer)

More Related