CVPR 03-25-14 08-09am Cardiac Ion Channels & Action Potentials - Beam

Question 1

In the heart, electrical activity…

Answer 1

1. Generates repetitive firing in specialized “pacemaker” regions…… 2. Propagates w/in the myocardium and via specialized conductive pathways……3. Serves as a trigger for contraction of the myocardium.

Question 2

Cardiac action potential trigger…

Answer 2

… increase in intracellular concentration of Ca2+ –> contraction of myocardium

Question 3

Cardiac action potentials are initiated by…

Answer 3

…pacemaker cells, which slowly depolarize to threshold in the absence of extrinsic input.

Question 4

Normally, heart rate is controlled by & modulated by …

Answer 4

… pacemaker cells in the SA node, which fire intrinsically at ~100/min…. Rate modulated by autonomic nervous system (slow to 60-80/min = parasympathetic tone)

Question 5

SA node

Answer 5

a cluster of small, round & spindle-shaped cells that contain few myofilaments, that are spontaneously active (automaticity), and that will fire APs at a frequency of ~100/min (rhythmicity); innervated by both sympathetic & parasympathetic axons.

Question 6

Parasympathetic innervations of SA node

Answer 6

Ongoing activity in parasympathetic axons (parasympathetic tone) typically slows the rate at which cells in the SA node fire to 60-80 action potentials/min.

Question 7

Automaticity of SA node vs. Automaticity of other cells (AV, etc.)

Answer 7

Cells in AV node and other heart regions may have automaticity, but the frequency at which they would fire APs is lower (slower) than the frequency of discharge SA node cells….Consequently, the SA node dominantes the pacemaker frequency & the other cells are normally driven by the SA node’s APs (overdrive suppression)

Question 8

Ectopic pacemakers

Answer 8

Under abnormal circumstances cells outside of the SA node that have spontaneous activity (especially cells in damaged regions of the myocardium) can take over initiation of the heartbeat from the SA node

Question 9

Coordination of contraction – what must occur

Answer 9

B/c heart rate is controlled by electrical activity of the SA node, the propagation of this activity to other regions of the heart has to occur such that the two atria contract and relax in a coordinated fashion, that two ventricles contract and relax in a coordinated fashion, and that ventricular contraction occurs during atrial relaxation (and vice versa).

Question 10

Coordination of contraction - how

Answer 10

1. Gap junctions connecting individual myocytes provide for cell-to-cell propagation of action potentials w/in the atrial myocardium, as well as w/in the ventricular myocardium……. 2. Specialized conductive pathways, in which individual cells are also connected by gap junctions, conduct the AP from SA node to left atrium and to AV node.

Question 11

Atrioventricular node (AV node)

Answer 11

A cluster of small cells located on the right side of the inter-atrial septum near the opening of the coronary sinus…. In normal heart, the only place where APs can spread from atria (SA node) to the ventricles; Elsewhere, myocardial cells in the atria are electrically insulated from those in the ventricles by an intervening layer of CT

Question 12

Conducting from the AV node

Answer 12

Additional conducting pathways propagate the action potential to the left & right ventricles. Cells in these conducting pathways are relatively large in diameter, so that the APs propagate more rapidly through them than through typical myocardial cells (which are half the size)

Question 13

Trigger for Contraction

Answer 13

In myocardium, AP lasts a few hundred ms & triggers a sustained contraction of about the same duration….APs in SA & AV nodes are somewhat briefer, but still much longer than the APs in skeletal muscle (only last ~1 ms)

Question 14

Sodium current (INa)

Answer 14

Cardiac sodium channels (containing NaV1.5 as the principle subunit) are similar to sodium channels in neurons and skeletal muscle…..Depolarization causes them to activate rapidly and then inactivate (voltage-gated).

Question 15

Calcium currents (ICa)

Answer 15

Properties of Ca2+ channels are mainly determined by the principle (CaV) subunit, which has a structure like that of the NaV subunit of voltage-gated sodium channels.

Question 16

High voltage activated (HVA) Calcium Currents (ICa)

Answer 16

1. L-type channels: CaV 1.1, 1.2, 1.3, 1.4 ……2. Neuronal channels: CaV2.1, 2.2, 2.3

Question 17

Low voltage activated (LVA) Calcium Channels

Answer 17

T-type channels: CaV3.1, 3.2, 3.3

Question 18

L-type calcium channels containing CaV1.2

Answer 18

Predominant in ventricular & atrial myocardium and cells of SA & AV nodes and conductive pathways

Question 19

L-type channels containing CaV1.3

Answer 19

Expressed alongside predominant Cav1.2 in SA nodal cells

Question 20

L-type channels – activation & inactivation

Answer 20

Activate rapidly in response to depolarization & subsequently inactivate in a manner dependent both on voltage (voltage-dependent inactivation, VDI) and cytoplasmic calcium (calcium-dependent inactivation, CDI).

Question 21

Locations of L-type channels (besides in the heart)

Answer 21

Expressed in smooth & skeletal muscle and in the nervous system.

Question 22

L-type calcium currents (ICa-L) are blocked by…

Answer 22

Dihydropyridines (nifedipine, for example) —– used as anti-hypertensive agents
— I-CaL channels are called dihydropyridine receptors (DHPR)

Question 23

HVA (High voltage activated) vs. LVA (Low voltage activated) channels

Answer 23

LVA (T-type channels) means they are activated by weaker depolarizations than those required for activation of HVA channels (L-type and Neuronal).

Question 24

I-CaL type vs. I-CaT type channels - activation dependint on

Answer 24

I-CaL both voltage- & Ca2+- dependent…..I-CaT are only voltage-dependent

Question 25

T-type channels location

Answer 25

Expressed in SA node & in nervous system

Question 26

Potassium channels - subunits

Answer 26

Unlike Na+ & Ca2+ channels, the principle subunits of K+ channels assemble as tetramers. Multiple genes encode subunits of the tetrameric channels, and in some instances hetero-tetramerization may occur between these gene products.

Question 27

Time-dependent potassium currents

Answer 27

IKto (Kv4.3 tetramer + KChiP2) ……AND…….. IKr (HERG tetramer + miRP1) ……AND….. IKs (KvLQT1 tetramer + mink)

Question 28

IKto – (Kv4.3 tetramer + KChiP2) – activation & inactivation

Answer 28

Voltage-dependent inactivation (Depolarization causes both activation & inactivation on a time scale only slightly slower than that of sodium current.)

Question 29

IKr (HERG tetramer + miRP1) & IKs (KvLQT1 tetramer + minK)

Answer 29

“Rapid” delayed rectifier and “slow” delayed rectifier, respectively. Depolarization causes activation of these two currents on a time scale of 20-100 ms.

Question 30

Inward Rectifier potassium currents

Answer 30

IK1 and IKACh

Question 31

IK1 - type of channel, type of tetramer

Answer 31

An “inward rectifier” channel (Kir tetramer)

Question 32

IK1 - gating

Answer 32

Not gated in conventional sense, but its conductance is steeply voltage-dependent as a consequence of block by cytoplasmic constituents —> these channels display a strong, “instantaneous” (< 1 ms) rectification such that they readily conduct inward K+ current at potentials below EK & only weakly pass outward K+ current at potentials slightly positive to EK

Question 33

IK1 – action

Answer 33

Hold cells near EK btwn APs w/out producing an outward current upon depolarization that would be energetically costly & make it more difficult to generate an AP

Question 34

IKACh - channel type, tetramer type

Answer 34

An “inward rectifier channel” (GIRK tetramer)

Question 35

IKACh increase & role

Answer 35

Increased by activation of muscarinic receptors (in response to ACh) = Important for ability of parasympathetic nervous system to slow pacemaker activity of the SA node.

Question 36

Non-selective / Time-dependent cation current

Answer 36

If (or Ih)

Question 37

If (or Ih) - activation/inactivation

Answer 37

Considered “funny” (hence the “f“) b/c it is turned off at depolarized potentials & turned on at hyperpolarized potentials (hence the “h” in Ih)….. Permeable to both Na+ & K+ (Erev ~ -30 mV)

Question 38

If (Ih) role

Answer 38

Possibly plays important role in pacemaking SA nodal cells

Question 39

Categorization of cardiac APs as fast or slow is based on…

Answer 39

… whether the initial upstroke is rapid or slow

Question 40

Phase 0 of Fast Cardiac APs

Answer 40

Initial upstroke (phase 0) consists of rapid depolarization caused by entry of Na+ (INa) through voltage-activated sodium channels. The rapid upstroke of fast cardiac APs is an indicator of the much faster spatial propagation than occurs for slow action potentials.

Question 41

Phases 1 of Fast Cardiac APs

Answer 41

Following the rapid upstroke (phase 0) is a small, partial repolarization (phase 1), which is produced by a combination of inactivation of sodium current & activation of a transient potassium current IKto.

Question 42

Phase 2 of Fast Cardiac APs

Answer 42

After the repolarization brough on in phase 1 by the inactivation of Na current and activation of IKto, phase 2 occurs with a prolonged plateau, during which voltage-activated, L-type calcium channels are open….The influx of Ca2+ (ICa-L) is ~balanced by an efflux of K+ (IKr and IKs) via delayed rectifier channels so that membrane potential remains at a roughly constant level (near 0 mV) during the plateau.

Question 43

Phase 3 of Fast Cardiac APs

Answer 43

After the plateau of Phase 4, the combination of inactivation of (ICa) and increased activation of IKr and IKs causes termination of the plateau by a rapid repolarization (phase 3).

Question 44

Phase 4 of Fast Cardiac APs

Answer 44

As a result of the rapid repolarization of phase 3, IKr and IKs are de-activated, and inactivation of INa and ICa is removed; the cell is held near EK by the inward rectifier (IK1)

Question 45

Initiation of a second AP

Answer 45

A second action potential cannot be initiated (absolute refractory period) until most of the inactivation of INa is removed (during the repolarizing phase), and the threshold for a second APs remains elevated (relative refractory period) until after repolarization is complete (complete removal of inactivation of INa and deactivation of IKr and IKs has occurred).

Question 46

Differences between ionic currents in pacemaker cells of SA & AV nodes and those in cells of the myocardium & fast conducting pathways.

Answer 46

Most notably, pacemaker cells have reduced INa & little IK1…Also, pacemaker cells express If and ICa-T which are essentially absent in myocardial cells.

Question 47

Result of the complement of ionic currents expressed in pacemaker cells

Answer 47

No stable resting potential; These cells produce repetitive, “slow action potentials.”

Question 48

Phase 0 of Slow Cardiac APs

Answer 48

An upstroke attributable to activation of ICa-T and ICa-L, which is relatively slow owing to the absence of INa.

Question 49

Phase 1 & 2 in Slow Cardiac APs

Answer 49

Slow cardiac action potentials lack the partial repolarization (phase 1) & prolonged plateau (phase 2) characteristic of fast action potentials

Question 50

Phase 3 in Slow Cardiac APs

Answer 50

Rather than phases 1&2 (partial repolarization & prolonged plateau) of fast cardiac APs, the balance between ICa and delayed rectifier current (IKr & IKs) is such that repolarization (phase 3) occurs shortly after the peak of the action potential.

Question 51

Phase 4 of Slow Cardiac APs

Answer 51

Repolarization in Phase 3 is followed by a slow depolarization (the “pacemaker potential”) during phase 4, which brings the cell back to threshold for the generation of another AP

Question 52

Pacemaker potential & If (funny current)

Answer 52

One contributor of likely importance to the pacemaker potential is the funny current (If) which is induced by hyperpolarization —> allows cation fluxes (Na+ and to a slightly lesser extent K+) —> drive voltage towards the reversal potential of If (-30 mV)

Question 53

Pacemaker potential – other current contributors (other I’s than If)

Answer 53

The pacemaker depolarization during phase 4 of slow cardiac action potentials is also likely facilitated by the slow deactivation of IKr and IKs, and by activation of LVA Ca2+ current (ICa-T).

Question 54

Rhythmic firing of pacemaker cells

Answer 54

1. Ion channels present in plasma membrane of pacemaker cells provide highly plausible mechanism for rhythmic firing……..2. Also suggested that INTERNAL CALCIUM RELEASE & the resultant movements of Na+ and Ca2+ via NCX SODIUM/CALCIUM EXCHANGER play an important role in generating the pacemaker potential

Question 55

IKr (tetramer of HERG) & preclinical evaluation of new drugs

Answer 55

B/c of its importance for repolarization of both fast & slow cardiac action potentials, altered HERG function can disrupt normal cardiac electrical activity, leading to arrhythmias === significant in regard to clinically administered drugs b/c HERG channels are blocked by a wide variety of structurally unrelated compounds…..Thus, now standard practice that early pre-clinical tests of any investigational drug must determine whether it blocks HERG channels.

Question 56

Ion channel basics

Answer 56

1. Channels “gate” open/closed. 2. Direction of current flow depends on membrane potential (Vm) & ion gradient (Nernst potential, E-ion). 3. Current flowing into cell causes depolarization; Current flowing out causes hyperpolarization

Question 57

Vm vs. E-ion and direction of ion flow

Answer 57

If VmE-ion, current flows out of the cell

Question 58

Locations of slow APs

Answer 58

SA node, AV node

Question 59

Locations of fast APs

Answer 59

Myocardium, ventricular muscles, specialized conductive pathways (such as Purkinje fibers)

Question 60

Difference between fast & slow APs depends on

Answer 60

Types of ion channels in these tissue types

Question 61

Nernst potential (E-ion) of Na, Ca, K

Answer 61

E-Na = +58…..E-Ca = +124……E-K = -90

Question 62

Direction of propagation of APs in the heart is controlled by…

Answer 62

Gap junction position & by connective tissue “insulation” (btwn atria & ventricles)

Question 63

Channel structure:

Answer 63

Pore w/activation gate (voltage-gated; open when voltage becomes more positive) on intracellular side

Question 64

Activation of I-Na, I-Ca-L, I-Ca-T

Answer 64

Current (+charge movement) is always inward b/c can’t be more positive than E-Na or E-Ca (If VmE-ion, current flows out)

Question 65

Activation of transient inward outward I-K

Answer 65

Always outward (positive charge exits) b/c can’t get to voltage more negative than E-K (If VmE-ion, current flows out)

Question 66

Currents during the Phases of FAST Cardiac AP

Answer 66

Phase 0 = I-Na (activates then inactivates again)……Phase 2 = I-Ca-L (long lasting)……..Phase 1 = transient outward current I-Kto………..Phase 3 = I-Kr & I-Ks delayed rectifier current……. Phase 4 = I-K1 inward rectifier current (see slide 12)

Question 67

Currents during the Phases of of SLOW Cardiac AP

Answer 67

Phase 0 – activation of I-CaT & I-CaL………. Phase 3 = If…….Phase 4 = I-Kr, I-Ks delayed rectifier currents

Question 68

Pacemaker depolarization - what it is & how it is accomplished

Answer 68

Spontaneous tendency to depolarize & create APs <— Turning on of If, Activation of I-CaT, Deactivation of I-Kr / I-Ks