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AP Bio Cell Membrane

Membrane Structure

  • Phospholipids

  • Proteins

  • Cholesterol

Phospholipids

  • Have a polar “head”

    • Phosphate

  • Have 2 nonpolar “tails”

    • Fatty Acids

  • Polar side is attracted to water

  • Nonpolar side is repelled to water

  • Can have saturated hydrocarbon chains

    • Making the membrane viscous

  • Can have unsaturated hydrocarbon chains

    • Making the membrane more fluid

  • Move laterally, but rarely flip flop

Proteins

  • Used for moving substances in and out of the cell

  • Used for signal recognition

  • Are embedded in the phospholipid bilayer based on hydrophobic interactions

  • Can be integral

    • Through the cell membrane

  • Glycoproteins are also common

Cholesterol

  • Helps the membrane deal with temperature changes

  • Keeps the membrane fluid when cooled

    • Keeps the phospholipids from packing tightly

  • Keeps the membrane viscous when heated

    • Restrains the movement of molecules

Movement Across Membranes

Passive Transport

  • Diffusion across the membrane

  • No energy required

  • Spontaneous

  • Examples :

    • Diffusion

    • Osmosis

    • Facilitated Diffusion

Active Transport

  • Often moves particles against the concentration gradient.

  • Occasionally moves with the c.g., but at a faster rate than diffusion.

  • Occurs when you need to accumulate particles

  • Requires energy to move molecules

  • Energy is required

  • ATP used

  • Examples :

    • The sodium-potassium pump

      • Involved with nerve cells

      • The transport protein has 2 conformations :

        • High affinity for Na+ with binding sites oriented toward the cytoplasm

        • High affinity for K+ with binding sites toward the exterior

      • ATP phosphorylates the transport protein and powers the conformational change from Na+ receptive to K+ receptive

      • 3 Na+ are moved out of the cell leaving room for 2 K+

      • This sets up an electrochemical gradient across the membrane

        • The difference in charge across a membrane is called the membrane potential

        • The combination of the membrane potential and the concentrations gradient is called the electrochemical gradient

      • With the correct stimulus, a gated channel opens

      • The electrochemical gradient is equalized

      • This is a nerve impulse

      • The nerve can’t work again until the gradient is set up

Diffusion

  • Due to random movement of molecules

  • Particles have a net movement from high concentration to low concentration

  • Remember entropy

  • Concentration gradient

    • Is the difference in concentration throughout space

    • Particles tend to move “with” or “down” their concentration gradient

    • From high concentration to low concentration

  • Equilibrium

    • When the concentration is the same throughout space

Osmosis

  • The diffusion of water across a membrane

  • Moves down its concentration gradient

    • Toward higher concentration of particles

  • Very important in cellular biology

  • Water will move from a hypotonic solution to a hypertonic solution

  • Hypotonic solution

    • Contains less solute (more water) than a hypertonic solution

  • Hypertonic solution

    • Contains more solute (less water) than a hypotonic solution

  • Water will move from a hypotonic solution to a hypertonic solution until :

    • Both solutions have equal concentrations (isotonic)

    • The pressure of the cell wall in plants stops the movement of water

Aquaporins

  • Due the polarity of water, it has a difficult time moving directly through the membrane

  • Water moves through protein channels called aquaporins

Water Control in Cells Without Cell Walls

  • In isotonic environment, cells will stay the same (good)

    • There is no net movement of water

    • Cells become limp or flaccid.

    • Plant will wilt

  • In hypertonic environment, cell will loose water and shrivel (crenate)

    • Cells will loose water

    • Plasmolysis may occur

      • When membrane pulls away from cell wall

    • Usually fatal to plant cells.

  • In hypotonic environment, cell will gain water and swell

    • Water moves into the cell until the internal pressure of the cell wall equals the osmotic pressure

    • At this point, there is equal movement in and out of the cell.

    • Dynamic equilibrium

    • Ideal for most plants.

    • Turgor pressure builds (cells are turgid).

  • If water uptake is excessive, the cell could burst (lyse)

  • Organelles such as contractile vacuoles keep freshwater protists from bursting

Facilitated Diffusion

  • Some molecules can’t diffuse freely across the membrane because they are too big or too charged

  • They need the help of proteins.

  • Facilitated diffusion

    • Is the diffusion of solute across a membrane with the help of transport proteins

  • Does not require energy.

  • Moves with the concentration gradient

Transport Proteins

  • Solute specific

  • Can be saturated

  • Use various mechanisms for transport such as :

    • Conformational change

    • Selective channels

  • Gated channels (only open with impulse)

Endocytosis

  • Import particles into a cell by the formation of a vesicle

Three types are :

  • Phagocytosis

    • “Cell eating”

    • Endocytosis of solid (large) particles

    • This is how amoebas eat

  • Pinocytosis

    • “Cell Drinking”

    • Endocytosis of fluid droplets (small particles)

  • Receptor mediated endocytosis

    • Happens when a specific molecule (called a ligand) binds to a receptor on the cell membrane

Exocytosis

  • Exporting particles out of a cell by fusing a vesicle with the cell membrane

Z

AP Bio Cell Membrane

Membrane Structure

  • Phospholipids

  • Proteins

  • Cholesterol

Phospholipids

  • Have a polar “head”

    • Phosphate

  • Have 2 nonpolar “tails”

    • Fatty Acids

  • Polar side is attracted to water

  • Nonpolar side is repelled to water

  • Can have saturated hydrocarbon chains

    • Making the membrane viscous

  • Can have unsaturated hydrocarbon chains

    • Making the membrane more fluid

  • Move laterally, but rarely flip flop

Proteins

  • Used for moving substances in and out of the cell

  • Used for signal recognition

  • Are embedded in the phospholipid bilayer based on hydrophobic interactions

  • Can be integral

    • Through the cell membrane

  • Glycoproteins are also common

Cholesterol

  • Helps the membrane deal with temperature changes

  • Keeps the membrane fluid when cooled

    • Keeps the phospholipids from packing tightly

  • Keeps the membrane viscous when heated

    • Restrains the movement of molecules

Movement Across Membranes

Passive Transport

  • Diffusion across the membrane

  • No energy required

  • Spontaneous

  • Examples :

    • Diffusion

    • Osmosis

    • Facilitated Diffusion

Active Transport

  • Often moves particles against the concentration gradient.

  • Occasionally moves with the c.g., but at a faster rate than diffusion.

  • Occurs when you need to accumulate particles

  • Requires energy to move molecules

  • Energy is required

  • ATP used

  • Examples :

    • The sodium-potassium pump

      • Involved with nerve cells

      • The transport protein has 2 conformations :

        • High affinity for Na+ with binding sites oriented toward the cytoplasm

        • High affinity for K+ with binding sites toward the exterior

      • ATP phosphorylates the transport protein and powers the conformational change from Na+ receptive to K+ receptive

      • 3 Na+ are moved out of the cell leaving room for 2 K+

      • This sets up an electrochemical gradient across the membrane

        • The difference in charge across a membrane is called the membrane potential

        • The combination of the membrane potential and the concentrations gradient is called the electrochemical gradient

      • With the correct stimulus, a gated channel opens

      • The electrochemical gradient is equalized

      • This is a nerve impulse

      • The nerve can’t work again until the gradient is set up

Diffusion

  • Due to random movement of molecules

  • Particles have a net movement from high concentration to low concentration

  • Remember entropy

  • Concentration gradient

    • Is the difference in concentration throughout space

    • Particles tend to move “with” or “down” their concentration gradient

    • From high concentration to low concentration

  • Equilibrium

    • When the concentration is the same throughout space

Osmosis

  • The diffusion of water across a membrane

  • Moves down its concentration gradient

    • Toward higher concentration of particles

  • Very important in cellular biology

  • Water will move from a hypotonic solution to a hypertonic solution

  • Hypotonic solution

    • Contains less solute (more water) than a hypertonic solution

  • Hypertonic solution

    • Contains more solute (less water) than a hypotonic solution

  • Water will move from a hypotonic solution to a hypertonic solution until :

    • Both solutions have equal concentrations (isotonic)

    • The pressure of the cell wall in plants stops the movement of water

Aquaporins

  • Due the polarity of water, it has a difficult time moving directly through the membrane

  • Water moves through protein channels called aquaporins

Water Control in Cells Without Cell Walls

  • In isotonic environment, cells will stay the same (good)

    • There is no net movement of water

    • Cells become limp or flaccid.

    • Plant will wilt

  • In hypertonic environment, cell will loose water and shrivel (crenate)

    • Cells will loose water

    • Plasmolysis may occur

      • When membrane pulls away from cell wall

    • Usually fatal to plant cells.

  • In hypotonic environment, cell will gain water and swell

    • Water moves into the cell until the internal pressure of the cell wall equals the osmotic pressure

    • At this point, there is equal movement in and out of the cell.

    • Dynamic equilibrium

    • Ideal for most plants.

    • Turgor pressure builds (cells are turgid).

  • If water uptake is excessive, the cell could burst (lyse)

  • Organelles such as contractile vacuoles keep freshwater protists from bursting

Facilitated Diffusion

  • Some molecules can’t diffuse freely across the membrane because they are too big or too charged

  • They need the help of proteins.

  • Facilitated diffusion

    • Is the diffusion of solute across a membrane with the help of transport proteins

  • Does not require energy.

  • Moves with the concentration gradient

Transport Proteins

  • Solute specific

  • Can be saturated

  • Use various mechanisms for transport such as :

    • Conformational change

    • Selective channels

  • Gated channels (only open with impulse)

Endocytosis

  • Import particles into a cell by the formation of a vesicle

Three types are :

  • Phagocytosis

    • “Cell eating”

    • Endocytosis of solid (large) particles

    • This is how amoebas eat

  • Pinocytosis

    • “Cell Drinking”

    • Endocytosis of fluid droplets (small particles)

  • Receptor mediated endocytosis

    • Happens when a specific molecule (called a ligand) binds to a receptor on the cell membrane

Exocytosis

  • Exporting particles out of a cell by fusing a vesicle with the cell membrane

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