CELLULAR PHYSIOLOGY

Question 1

What are the components of a cell membrane?

Answer 1

1. Cholesterol
2. Phospholipids
3. Sphingolipids
4. Glycolipids
5. Proteins

Question 2

Which cell membrane component contributes the most to stability?

Answer 2

Cholesterol

Question 3

What are the two molecular components of cell membrane phospholipids?

Answer 3

Glycerol backbone (hydrophilic) and fatty acid chains (hydrophobic)

Question 4

How are integral and peripheral proteins different?

Answer 4

Integral: span entire membrane
Peripheral: located on either side of the membrane

Question 5

How are integral proteins attached to the membrane?

Answer 5

Hydrophobic interactions with the phospholipid bilayer

Question 6

Give some examples of integral and peripheral proteins:

Answer 6

Integral: ion channels, transport proteins
Peripheral: spectrin, ferrochelatase (an example of a membrane-linked enzyme)

Question 7

How do lipid-soluble substances move across cell membranes?

Answer 7

Simple diffusion across the hydrophobic lipid bilayer

Question 8

How do water-soluble substances move across cell membranes?

Answer 8

Cross through water-filled channels or transported by carriers, as they cannot dissolve in the lipid bilayer

Question 9

What are the different types of transport across a cell membrane?

Answer 9

Simple diffusion, facilitated diffusion, primary active transport, and secondary active transport

Question 10

Which types of cellular transport are carrier mediated?

Answer 10

Facilitated diffusion, primary active transport, and secondary active transport

Question 11

Which types of cellular transport require metabolic energy?

Answer 11

Primary active transport and secondary active transport

Question 12

What is an example of a primary active transporter?

Answer 12

Any ion-translocating ATPase

Question 13

What are the two subtypes of secondary active transporters?

Answer 13

1. Cotransport
2. Countertransport

Question 14

What is cotransport (symport)?

Answer 14

Mediated transfer of two or more solutes in the same direction across a cell membrane

Question 15

What is countertransport (antiport)?

Answer 15

Mediated transfer of two or more solutes in opposite directions across a cell membrane

Question 16

Explain secondary active transport:

Answer 16

It couples the transfer of two or more solutes across a membrane; one solute moves down its electrochemical gradient providing the motive force for movement of the other solute(s) against its electrochemical gradient

Question 17

Which ion most often functions as the motive force for secondary active transport?

Answer 17

Na+; it has a favorable inward gradient across almost all cell membranes

Question 18

What is the direction of solute movement relative to the electrochemical gradient in
the following types of transport?

SIMPLE DIFFUSION

Answer 18

downhill

Question 19

What is the direction of solute movement relative to the electrochemical gradient in
the following types of transport?

FACILITATED DIFFUSION

Answer 19

downhill

Question 20

What is the direction of solute movement relative to the electrochemical gradient in
the following types of transport?

PRIMARY ACTIVE TRANSPORT

Answer 20

uphill

Question 21

What is the direction of solute movement relative to the electrochemical gradient in
the following types of transport?

SECONDARY ACTIVE TRANSPORT

Answer 21

For both types of transport one solute moves down its gradient providing energy for the other solutes to move against their gradients. In cotransport, solutes move in the same direction. In countertransport, they move in opposite directions.

Question 22

What does permeability describe?

Answer 22

Ease with which a solute is able to diffuse across a membrane

Question 23

What factors can increase membrane permeability?

Answer 23

1. Increased oil/water partition coefficient
2. Decreased size of solute
3. Decreased membrane thickness

Question 24

What are the characteristics that are important in carrier-mediated transport?

Answer 24

Stereospecificity, saturation, and inhibition (competitive, noncompetitive)

Question 25

What is the transport rate when the carriers are saturated?

Answer 25

Transport maximum (Tm)

Question 26

Which is faster, diffusion or facilitated diffusion of a hydrophilic solute?

Answer 26

Facilitated diffusion, as it is carrier mediated

Question 27

Which has unlimited (theoretically) capacity for cellular transport?

Answer 27

Diffusion, it is limited only by its gradient and its permeability characteristics

Question 28

What is the Na+-K+ pump?

Answer 28

An integral membrane protein mediating ATP hydrolysis as energy for Na+-K+ exchange

Question 29

What does the Na+-K+ pump do?

Answer 29

Extrudes 3 Na+ from within the cell and takes in 2 K+ from outside the cell

Question 30

Is the Na -K pump electroneutral?

Answer 30

No; the Na -K pump is electrogenic, mediating net efflux of positive charge creating a negatively charged interior of the cell.

Question 31

What provides the energy for the Na+-K+ pump?

Answer 31

Hydrolysis of adenosine triphosphate (ATP)

Question 32

What example substances inhibit activity of the Na+-K+ ATPase pump?

Answer 32

Ouabain and digitalis glycosides (cardiac glycosides)

Question 33

What are some examples of intercellular connections?

Answer 33

Tight junctions, gap junctions, and desmosomes

Question 34

What is the role of tight junctions? (Histology often calls these zonula occludens.)

Answer 34

Circumferential bands of proteins that impede the movement of solute paracellularly

Question 35

Tight junctions have been classically divided into tight and leaky epithelia. Explain the difference and give examples:

Answer 35

Tight: many bands of protein blocking all (most) paracellular movement of water and solute; found in the ascending limb of the loop of Henle Leaky: few bands of protein, allows paracellular movement of water; found in the proximal tubule and throughout the gut

Question 36

What is the role of desmosomes? (Histology often calls these zonula adherens.)

Answer 36

These are regions of connections between adjacent cells. They permit paracellular movement, but do not allow for cell-to-cell flow.

Question 37

What is the role of gap junctions?

Answer 37

Protein bridges from one cell to an adjacent cell. These allow for solute flow between adjacent cells.

Question 38

What important tissue relies on gap junctions for proper function?

Answer 38

Myocardium, allow for rapid conduction of electrical impulses

Question 39

Define osmolarity:

Answer 39

Concentration of osmotically active particles in a solution

Question 40

Define osmosis:

Answer 40

Flow of water across a semipermeable membrane from a low osmolarity compartment to a compartment with a higher osmolarity

Question 41

Define osmotic pressure:

Answer 41

The hydrostatic pressure necessary to counter osmosis between two compartments

Question 42

How is osmotic pressure calculated?

Answer 42

Van’t Hoff’s law: π = gCRT π = osmotic pressure (mm Hg), g = number of particles in solution (osm/mol), C= concentration (mol/L), R = gas constant (0.082 L . atm/mol . K), T= absolute temperature (K)

Question 43

What is oncotic pressure?

Answer 43

Osmotic pressure created by proteins (e.g., colloid osmotic pressure)

Question 44

What is tonicity?

Answer 44

The relative difference in osmolarity in different compartments

Question 45

What are hypotonic and hypertonic solutions?

Answer 45

These terms refer to the relationship between two compartments. Hypotonicity refers to a relatively lower osmolarity of one compartment to another. Hypertonicity, likewise, refers to a solution having higher osmolarity than another

Question 46

How does infusion of hypo/hypertonic solutions influence fluid compartments?

Answer 46

Infusion of a hypotonic solution into the intravascular space will initially decrease osmolarity, and water will tend to move into the interstitium, increasing edema. Infusion of hypertonic fluids will lead to the opposite effect.

Question 47

Define steady state:

Answer 47

The stable condition between biologic compartments when the net ionic flow is zero

Question 48

Define diffusion potential:

Answer 48

Potential difference across a membrane due to the separation of positive and negative charge across a membrane

Question 49

What determines the size of the diffusion potential?

Answer 49

The magnitude of the ionic charge separation

Question 50

Can a diffusion potential be generated if the membrane is not permeable to the ion?

Answer 50

No

Question 51

What determines the sign of the diffusion potential?

Answer 51

The direction of the positive and negative charge separation across the membrane

Question 52

True or False? Creation of the diffusion potential requires the movement of a significant number of ions.

Answer 52

False. The separation of very few ions creates a diffusion potential.

Question 53

What facilitates the movement of ions across the membrane?

Answer 53

Typically, ion channels, but also pumps and carrier transporters

Question 54

What controls the opening and closing of ion channels?

Answer 54

A molecular gating mechanism

Question 55

What are the three general components of an ion channel?

Answer 55

1. The pore 2. The selectivity filter 3. The gating mechanism

Question 56

What is the selectivity filter?

Answer 56

Grants specificity to the various channels, allowing only one type of ion through the channel

Question 57

What does the conductance of an ion channel depend on?

Answer 57

The probability that the channel is open and its capacity to mediate translocation through the pore

Question 58

What types of ion channel gating mechanisms are there?

Answer 58

Voltage-sensitive, ligand-induced, and mechanical gates

Question 59

What controls the opening of voltage-gated channels?

Answer 59

Membrane potential

Question 60

What controls the opening and closing of ligand-gated channels?

Answer 60

Hormones Second messengers Neurotransmitters

Question 61

What controls the opening of mechanical gates?

Answer 61

Membrane stretch and manipulation. Commonly seen in epithelial layers

Question 62

Define equilibrium potential (£):

Answer 62

Electrical potential that exactly opposes diffusion caused by an ionic concentration difference. (In other words: how much energy do we have to use to stop diffusion)

Question 63

What is it called when the electrical and chemical driving forces of an ion are equally opposed?

Answer 63

Electrochemical equilibrium

Question 64

What equation is used to calculate equilibrium potentials?

Answer 64

Nernst equation (E = (-2.3RT/xF)(log([Ci]/[Ce])))

Question 65

What are the approximate values of the equilibrium potential for Na+ in nerves and muscles?

Answer 65

+65 mV

Question 66

What are the approximate values of the equilibrium potential for K+ in nerves and muscles?

Answer 66

-85 mV

Question 67

What are the approximate values of the equilibrium potential for Ca2+ in nerves and muscles?

Answer 67

+120 mV

Question 68

What are the approximate values of the equilibrium potential for Cl- in nerves and muscles?

Answer 68

-85 mV

Question 69

Define the resting membrane potential.

Answer 69

Electrical potential across a semipermeable membrane when the cell is at steady state

Question 70

Is energy consumed to generate the resting membrane potential?

Answer 70

Yes, the maintenance of the ionic gradients requires constant energy input

Question 71

Define depolarization:

Answer 71

Membrane potential becomes less negative (i.e., −60 mV → −40 mV)

Question 72

Define hyperpolarization:

Answer 72

Membrane potential becomes more negative (i.e., −60 mV → −90 mV)

Question 73

What is a cell called if it is capable of producing an action potential?

Answer 73

Excitable

Question 74

What do action potentials consist of?

Answer 74

Rapid depolarization and repolarization

Question 75

What are the unique characteristics of action potentials?

Answer 75

All-or-none events, propagation, and stereotypical size and shape (differs for different cells, e.g., cardiac versus neurons but always reproducible in each cell type)

Question 76

What is the point after which an action potential is inevitable?

Answer 76

Threshold

Question 77

What does inward or outward current charge refer to?

Answer 77

Movement of positive charge into (inward) and out of (outward) the cell

Question 78

What is the resting membrane potential for nerve cells?

Answer 78

−70 mV

Question 79

What ion is primarily responsible for the resting membrane potential of nerve cells?

Answer 79

K+

Question 80

Why does K+ contribute the most to the resting potential?

Answer 80

At rest, K+ has the greatest ionic conductance

Question 81

What signals the activation gates of Na+ channels?

Answer 81

Depolarization of the cell membrane; these are voltage-gated channels

Question 82

What ion is responsible for the upstroke of the action potential in nerve cells?

Answer 82

Na+

Question 83

Define overshoot:

Answer 83

Peak of the action potential at which the membrane potential is positive

Question 84

What signals the inactivation gates of Na+ channels?

Answer 84

Depolarization of the cell membrane

Question 85

How can depolarization cause both activation and deactivation of Na+ channel gates?

Answer 85

Inactivation occurs more slowly than activation

Question 86

What causes repolarization of the cell membrane following an action potential?

Answer 86

As the inward Na+ conductance falls due to channel inactivation, outward K+ conductance leads to repolarization

Question 87

What signals the opening of K+ channels during an action potential?

Answer 87

Depolarization of the cell membrane

Question 88

What is the hyperpolarization of the afterpotential called?

Answer 88

Undershoot

Question 89

What causes undershoot?

Answer 89

K+ channels stay open after the Na+ channels close