1. Interactions Between Cells and the Extracellular Environment
Chapter 6
Interactions Between Cells and the Extracellular Environment
Lecture PowerPoint
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2. Extracellular Environment
The extracellular environment includes everything located outside the cells.
Cells receive nourishment from and release wastes into the extracellular environment.
Cells communicate with each other by secreting chemical regulators into the extracellular environment.

3. The Cell

4. Body Fluids
67% of our water is within cells in the intracellular compartment.
33% is in the extracellular compartment. Of this:
20% is in blood plasma.
80% makes up what is called tissue fluid, or interstitial fluid.

5. Extracellular Environment

6. Extracellular Matrix
Contains protein fibers and a gel-like ground substance
Protein fibers provide structural support.
Gel is composed of glycoproteins (composed of proteins and sugars) and proteoglycans (composed of polysaccharides).
Integrins are glycoproteins that extend from the cell cytoskeleton and bind to the extracellular matrix.

7. I. Intracellular / Extracellular Environment

8. Cell Transport
The plasma membrane is selectively permeable, meaning that it allows some molecules to cross but not others.
Generally not permeable to proteins, nucleic acids, or other large molecules
Generally permeable to ions, nutrients, and wastes

9. Categories of Membrane Transport
Carrier-mediated
Facilitated diffusion – follows the concentration gradient of the molecule or ion. Does not require energy use.
Active transport – carrier proteins are used as well, but transport against the concentration gradient of the ion. This requires the use of energy (ATP)

10. Categories of Membrane Transport
Noncarrier-mediated – does not require carrier proteins in the membrane.
Simple diffusion of lipid-soluble molecules (non-polar)
Simple diffusion of water = osmosis
Simple diffusion of ions through nonspecific channels

11. Categories of Membrane Transport
Passive transport: Molecules move from higher to lower concentration without using energy. They move along a concentration gradient. (downhill)
Active transport: Molecules move from lower to higher concentration using ATP. They move against a concentration gradient. (uphill)

12. Categories of Membrane Transport
Non-polar molecules can move through the phospholipid bilayer of the plasma membrane via simple diffusion.
Inorganic ions and water can move through protein channels via simple diffusion.
Small organic molecules (glucose) can move via facilitated diffusion using carrier proteins in the plasma membrane.

13. Checkpoint 1
1. The majority of water within the body is found in the  A. intracellular compartment. B. extracellular compartment. C. blood plasma. D. interstitial fluid.
2. The extracellular matrix is made up of collagen, elastin, and a gel-like ground substance. 
3. Active transport does not require the expenditure of energy. 
4. Proteins that extend from the cytoskeleton within the cell, through the plasma membrane, and into the extracellular matrix are  A. lysosomal proteins. B. metallo proteins. C. receptor proteins. D. integrin proteins.

14. II. Diffusion and Osmosis

15. Diffusion
Solution: consists of a solvent (water) and a solute (molecules dissolved in water)

16. Diffusion Molecules in a solution are in a constant state of motion.
If there is a concentration difference between two regions, random motion will establish equilibrium via diffusion.

17. Diffusion
Net diffusion: Due to random movement, the net direction of diffusion is from high to low solute concentration.
Will happen across a permeable membrane

18. Diffusion
A dialysis membrane is an artificial semipermeable membrane that will keep larger proteins inside while allowing smaller molecules and ions to pass through (along the concentration gradient).
Glucose can also pass through, but since there is equal concentration on both sides, no net movement occurs.

19. Diffusion Across the Plasma Membrane
Nonpolar (or uncharged) lipid-soluble molecules pass easily.
Oxygen, carbon dioxide, and steroid hormones
Gas exchange: net diffusion of O2 into cells and CO2 out of cells due to concentration
Opposite in lungs

20. Diffusion Across the Plasma Membrane

21. Diffusion Across the Plasma Membrane
Charged ions can pass through ion channels that cross the plasma membrane.
Channels may always be open or be gated.

22. Rates of Diffusion Depend on: Magnitude of concentration difference
Permeability of the membrane to the molecules
Temperature of the solution
Surface area of the membrane
Increased by microvilli

23. Osmosis
Because water molecules do not carry a charge, they can pass through the plasma membrane slowly.
Because this is the diffusion of solvent instead of solute, it is unique.
Aided by channels in membrane called aquaporins in some tissues

24. Osmosis
There must be a solute concentration difference on either side of a membrane permeable to water.
The membrane must be impermeable to the solute, or the concentration difference will not be maintained.
Solutes that cannot cross and permit osmosis are called osmotically active.

25. Osmosis
The net movement of water is from the side with more water (more dilute) to the side with less water (less dilute).
However, when osmosis is discussed, we say that water moves from an area of low solute concentration to an area of high solute concentration.

26. Osmosis
If we take a certain concentration of a solute (sucrose) and immerse it in water, where the sucrose concentration is lower, water will be drawn through the membrane until the concentrations are equal on both sides.

27. Osmotic Pressure
Osmotic pressure is the force surrounding a cell required to stop osmosis.
Can be used to describe the osmotic pull of a solution. A higher solute solution would require a higher osmotic pressure.

28. Osmotic Pressure
Look at the examples on the left. What can you tell me about the osmotic pressure of the 2 solutions?

29. Moles
A mole of a compound can be measured as its molecular weight in grams.
The number of atoms in 1 mole is always the same no matter the compound:
6.02 X molecules
(Avagadro’s number)
You can make molar solutions (1M) or molal solutions (1m).

30. Molarity
Glucose has a molecular weight of 180. To make a 1 molar solution of glucose, dissolve 180 g glucose in water to make 1 L solution.
NaCl has a molecular weight of To make a 1 molar solution of NaCl, dissolve 58.5 g NaCl in water to make 1 L solution.
Not useful for a discussion of osmosis, since the solute concentration is different depending on the solute. More water is used to make the 1 molar solution of NaCl.

31. Molality
1 molal solutions take the molecular weight in grams dissolved in exactly 1 L water.
The amount of water never changes, so you can compare solute concentrations to predict the direction of osmosis.

32. Osmolality Osmolality of sugar solutions
Osmolality is the total molality of a solution when you combine all of the molecules within it.
A 360 g (2m) glucose solution and a 180 g glucose (1m) g fructose (1m) solution would have the same osmolality.
These are both 2 Osm solutions.

33. Osmolality
Electrolytes that dissociate in water have to be assessed differently.
NaCl dissociates into Na+ and Cl- in water and must be counted as separate molecules.
A 1m NaCl solution would actually be a 2 Osm solution.

34. Osmolality and Ionization
If a membrane is permeable to water, but not solutes (Na, Cl, glucose), water will move into the more concentrated solution. In this example it would move toward the NaCl solution until equilibrium was reached.

35. Tonicity
Plasma has the same osmolality as a 5% dextrose or normal saline, which are used intravenously.
These solutions are considered isosmotic to plasma.
Tonicity is the effect of a solute concentration on the osmosis of water.
If a membrane separates a 5% dextrose solution and a normal saline solution, there will be no net movement of water = isotonic.

36. Tonicity
Tonicity takes into account the permeability of the membrane to the solutes. If the solutes can cross the membrane, the tonicity will change.

37. Tonicity
Solutions with a lower solute concentration than the cell are hypoosmotic and hypotonic. (If you place an RBC into fresh water)
Will pull water into the cell = lysis

38. Tonicity
Solutions with a higher solute concentration than the cell are hyper-osmotic and hypertonic. (If you place an RBC into sea water)
Will pull water out of the cell = crenation

39. Tonicity
The fate of red blood cells in isotonic, hypotonic, and hypertonic solutions

40. Regulation of Blood Osmolality
Constant osmolality must be maintained, or neurons will be damaged. Cannot have shrinking/swelling of cells in the brain.
Also neural activity is altered by ion concentrations (Ch 7)

41. Regulation of Blood Osmolality
Osmoreceptors in the hypothalamus detect increases in osmolality (due to dehydration). This triggers:
Thirst
Decreased excretion of water in urine
With a lower plasma osmolality, osmoreceptors are not stimulated, so more water is excreted in urine.

42. Checkpoint 2
1. Passive transport of water is known as  A. filtration. B. osmosis. C. facilitated diffusion. D. a water pump.
2. Dialysis uses the process of  A. facilitated diffusion. B. primary active transport. C. simple diffusion. D. secondary active transport.
3. The rate of diffusion increases as the concentration gradient increases. 
4. What type of intravenous fluid would be given to reduce edema?  A. hypertonic B. isotonic C. hypotonic
5. Explain the difference between osmolarity and osmolality.

43. III. Carrier-Mediated Transport

44. Carrier-Mediated Transport
Molecules that are large or polar cannot diffuse across the membrane.
Carrier proteins within the plasma membrane move these molecules across.
These proteins are specific to a given molecule.

45. Carrier-Mediated Transport
Some proteins can transport more than one molecule, but then there is a competition effect.
Transport rates increase with increased molecule concentration until saturation is met = transport maximum.

46. Facilitated Diffusion
Powered by the random movement of molecules--no ATP used
Net movement from high to low concentration
Requires specific carrier-mediated proteins

47. Facilitated Diffusion
Transport proteins may always exist in the plasma membrane or be inserted when needed.
Muscle cells do this during exercise to transport glucose.

48. Active Transport
Sometimes molecules must be moved from an area of low concentration to an area of high concentration.
This requires the expenditure of ATP.
Often, these carrier-mediated proteins are called pumps.

49. Primary Active Transport
Occurs when the hydrolysis of ATP is directly responsible for the protein function. The transport protein is also an ATPase enzyme.
Pump is activated by phosphorylation using a Pi from ATP.

50. The Ca2+ Pump
Located on all cells and in the endoplasmic reticulum of muscle cells
Removes Ca2+ from the cytoplasm by pumping it into the extracellular space
Creates a strong concentration gradient for rapid movement of Ca2+ back into the cell
Aids in release of neurotransmitter in neurons and in muscle contraction

51. Na+/K+ Pump Found in all body cells
ATPase enzyme that pumps 3 Na+ out of the cell and 2 K+ into the cell
Serves three functions:
Provides energy for coupled transport of other molecules
Produces electrochemical impulses in neuron and muscle cells
Maintains osmolality

52. Secondary Active Transport
Also called coupled transport
The energy needed to move molecules across their concentration gradient is acquired by moving sodium back into the cell.
Since the sodium was originally pumped out of the cell using ATP, this is considered active transport.

53. Secondary Active Transport
Cotransport: The other molecule is moved with sodium.
Common way to transport glucose
Countertransport: The other molecule is moved in the opposite direction from sodium.

54. Transport Across Epithelial Membranes
Involves transcellular transport: movement of molecules through the cytoplasm of the epithelial cells
May also involve paracellular transport: movement across the tiny gaps between cells - limited by junctional complexes:

55. Junctional Complexes
Tight junctions: where the membranes of the 2 cells actually join together. This does not allow easy diffusion between the cells.
Adherens junctions: where the membranes of the 2 cells are very close together and joined by intercellular “glue”
Desmosomes: where the membranes of the 2 cells are “buttoned” together my interactions between desmosomal proteins

56. Types of Junctional Complexes

57. Transport Across Epithelial Membranes
Involves many different types of carrier- mediated proteins at both ends of the epithelial cells
Example:
movement of glucose
across the intestinal
wall

58. Bulk Transport
Large molecules such as proteins, hormones, and neurotransmitters are secreted via exocytosis.
Involves fusion of a vesicle with the plasma membrane
Requires ATP

59. Bulk Transport
Movement of large molecules such as cholesterol into the cell requires endocytosis.
Usually a transport protein interacts with plasma membrane proteins to trigger endocytosis.

61. Checkpoint 3
1. Protein carrier mediated transport of molecules display  A. specificity. B. competition. C. saturation. D. All of these choices are correct.
2. Glucose can enter into the cell by facilitated diffusion or countertransport. 
3. Active transport carriers are also called  A. vesicles. B. channels. C. pumps. D. receptors.
4. What type of junctional complex will prohibit paracellular transport?  A. tight junctions B. adherens junctions C. desmosomes D. gap junctions
5. Movement of large molecules into a cell is called  A. endocytosis. B. exocytosis. C. bulk transport. D. Both A and C are correct.

62. IV. The Membrane Potential

63. Membrane Potential
There is a difference in charge on each side of the plasma membrane due to:
Permeability of the membrane
Action of Na+/K+ pumps
Negatively charged molecules inside the cell
The inside of the cell is negative compared to the outside.

64. Membrane Potential: K+
K+ accumulates at high concentrations in the cell because:
The Na+/K+ pumps actively bring in K+.
The membrane is very permeable to K+.
Negative anions inside the cell attract cations outside the cell.
Limited by strong concentration gradient.

65. Potential Difference
Even with all the K+ inside the cell, the negative molecules inside and all of the sodium outside make the cell more negative inside compared to outside.
This difference can be measured as a voltage.
Because the membrane is so permeable to K+, this difference is often maintained by K+.

66. K+ Equilibrium
The resulting potential difference measured in voltage would be the equilibrium potential for K+;
measured at −90mV.
This means the inside has a voltage 90mV lower than the outside.

67. Na+ Equilibrium
Sodium is also an important ion for establishing membrane potential.
The concentration of sodium in a normal cell is less inside than outside.
To keep so much sodium out, the inside would have to be positive to repel the sodium ions.

68. Na+ Equilibrium The equilibrium potential for sodium is +66mV.
The membrane is less permeable to Na+, so the actual membrane potential is closer to that of the more permeable K+.

69. Resting Membrane Potential
Membrane potential of a cell not producing any impulses. Depends on:
Ratio of the concentrations of each ion on either side of the membrane
Specific permeability to each ion
K+, Na+, Ca2+ and Cl− contribute to the resting potential.

70. Resting Membrane Potential
Membrane potential of a cell not producing any impulses
Because the membrane is most permeable to K+, it has the greatest influence.
A change in the permeability of the membrane for any ion will change the resting potential.
A change in the concentration of any ion inside or outside the cell will change the resting potential.
Key to how neurons work! (Ch 7)

71. Resting Membrane Potential
In most cells, the resting potential is between -65mV and -85mV.
Neurons are usually at −70mV.
Close to K+ equilibrium potential
When a neuron sends an impulse, it changes the permeability of Na+, driving the membrane potential closer to the equilibrium potential for Na+.

72. Role of Na+/K+ Pump Acts to counter K+ leaking out
Because it transports 2 K+ in for every 3 Na+ out, it maintains voltage difference.
Keeps both the resting potential and the concentration differences stable

74. Role of Na+/K+ Pump

75. Checkpoint 4
1. The charge difference across a membrane produces the membrane potential. 
2. The resting membrane potential is closest to the equilibrium potential for  A. sodium ions. B. chloride ions. C. calcium ions. D. potassium ions.
3. Hyperkalemia would ____________ the resting membrane potential of the cell.  A. increase B. decrease C. have no effect on
4. A change in the concentration of any ion inside or outside the cell will change the resting potential.

76. V. Cell Signaling

77. Cell Signaling Cells communicate using chemical signals. Types:
1. Gap junctions: allow adjacent cells to pass ions and regulatory molecules through a channel between the cells
2. Paracrine signaling: Cells within an organ secrete molecules that diffuse across the extracellular space to nearby cells.
Often called local signaling

78. Types of Cell Signaling

79. Cell Signaling Cells communicate using chemical signals. Types:
Synaptic signaling: involves neurons secreting neurotransmitters across a synapse to target cells
Endocrine signaling: involves glands that secrete hormones into the bloodstream; these can reach multiple target cells

80. Receptor Proteins
A target cell receives a signal because it has receptor proteins specific to it on the plasma membrane or inside the cell.
Polar or large signal molecules bind to receptors on the cell surface.

81. Receptor Proteins
Nonpolar signal molecules such as steroid hormones can penetrate the plasma membrane and interact with receptors inside the cytoplasm or nucleus.

82. Second Messengers
Some molecules may be too large or may be polar, and not be able to pass through the membrane.
Other proteins pass the information to the inside of the cell to effect change. These are called second messengers.

83. Second Messengers--cAMP
Cyclic adenosine monophosphate (cyclic AMP or cAMP) is a common second messenger.
A signaling molecule binds to a receptor.
This activates an enzyme that produces cAMP from ATP.
cAMP activates other enzymes.
Cell activities change in response.

84. G-Proteins
Receptor proteins that bind to a signal and enzyme proteins that produce a second messenger are rarely together. They require something to shuttle between them.
G-proteins are made up of 3 subunits.
One subunit dissociates when a signal molecule binds to the receptor and travels to the enzyme.

85. G-Proteins
1. When the receptor is not bound to the regulatory molecule, the 3 G-protein subunits are together and the α subunit binds GDP.

86. G-Proteins
2. Once the regulatory molecule attaches, the α subunit releases GDP and binds GTP, which dissociates α from βγ subunits.

87. G-Proteins
3. One of the subunits will move through the membrane and binds to an effector protein.

88. G-Proteins
The α subunit will split GTP into GDP and Pi and the G-protein will re-assimilate.
The effector protein may be an enzyme such as the one that produces cAMP.

89. Checkpoint 5
1. Which of the following is NOT a general category of cell signaling molecules?  A. endocrine signaling B. enzymatic signaling C. paracrine signaling D. synaptic signaling
2. Which of the following is NOT true of cyclic AMP?  A. It is found on the outside of a plasma membrane. B. It is a second messenger for polar regulatory molecules. C. It is made from ATP. D. It activates enzymes inside a cell to produce the desired effect.
3. Where is the receptor for a nonpolar, lipid-soluble regulatory molecule?  A. embedded in the outer surface of the plasma membrane B. embedded in the inner surface of the plasma membrane C. in the cytoplasm or nucleus of the cell D. All of the choices are correct.