CV & Vascular Signaling (complete)

Question 1

Describe the mechanisms by which PKA-mediated phosphorylation of L-type Ca++ channels affect inotropy and lusitropy

Answer 1

• L-type Ca++ channels are activated by depolarization
• Influx of Ca++ through these trigger RyR2 opening (SR Ca++ release)
• Sympathetic stimulation => ^ cAMP and ^ PKA
• PKA phosphorylates L-type channels => slowed inactivation
• Increases magnitude of Ca++ influx => inotropy

Question 2

Describe the mechanisms by which PKA-mediated phosphorylation of RyR2 affect inotropy and lusitropy

Answer 2

• Sympathetic stimulation => PKA phosphorylates RyRs
• This increases RyR sensitivity to Ca++ (less Ca++ needed to evoke SR Ca++ release)
• Increases inotropy

Question 3

Describe the mechanisms by which PKA-mediated phosphorylation of phospholamban (PLB) affect inotropy and lusitropy

Answer 3

• PLB inhibits SERCA
• PKA phosphorylates PLB => PLB dissociation from SERCA
• Increases Ca++ reuptake into SR
• Faster Ca++ reuptake => ^ lusitropy and ^ inotropy by increasing SR Ca++ load

Question 4

Describe the mechanisms by which PKA-mediated phosphorylation of troponin I (TnI) affect inotropy and lusitropy

Answer 4

• TnI inhibits troponin complex (inhibits actin-myosin interaction w/o Ca++)
• PKA (and other kinases) phosphorylate TnI => decreases Ca++ sensitivity of complex and ^ dissociation of Ca++ from complex
• This increases lusitropy => allows heart to fill more quickly

Question 5

Describe how hyperpolarization-activated cyclic nucleotide-gated (HCN) channels contribute to autonomic control of heart rate

Answer 5

• HCNs produce I(f) (an inward, depolarizing current)
• Sympathetic stimulation of the SA node cells => ^ cAMP => cAMP binds to HCNs
• HCNs now more likely to open => speeds rate of diastolic depolarization
• Parasympathetic stimulation (ACh) activates M2 muscarinic ACh receptor (coupled w/ Gi/o)
• This has opposite effect as sympathetic => decreases cAMP => less binding to HCNs => decrease I(f) through HCNs => slows HR

Question 6

Describe how L-type Ca++ channels contribute to autonomic control of heart rate

Answer 6

• ß-adrenergic stimulation increases L-type current => contributes to the sympathetic increase in HR
• Symp stimulation increase SR Ca++ load via PKA mediated phosphorylation of L-type channels and RyRs
• Parasymp stimulation via ACh activates M2 muscarinic Ach receptors => activates G(i) => slowing HR due to relaxation

Question 7

Describe how GIRK channels contribute to autonomic control of heart rate

Answer 7

• Gbg subunit binds to GIRK channels => activates IKACh current (K+) => hyperpolarizes cell
• This drives membrane potential to K+ equilibrium => slows spontaneous firing frequency

***This is the primary mechanism for parasympathetic regulation of HR

Question 8

Describe vascular smooth muscle cells (so that you can compare them with cardiac myocytes)

Answer 8

• Small, mononucleated cells
• Electrically coupled via gap junctions
• Not striated
• Not arranged in sarcomere
• SR Ca++ release not essential for contraction
• Contraction rate slows, sustained, and tonic
• Can be initiated by mechanical, electrical, or chemical stimuli
• Do NOT have troponin

Question 9

Describe cardiac myocytes (so that you can compare them with vascular SM cells)

Answer 9

• Striated
• Arranged in sarcomeres
• SR Ca++ release essential for contraction
• Contraction rate faster and unsustained

Question 10

Describe Ca++ regulation of vascular SM contraction

Answer 10

• Ca++ enters cytoplasm from SR & voltage-gated Ca++ channels
• Ca++ binds to calmodulin (CaM)
• Ca++-CaM binds to myosin light chain kinase (MLCK) => activates
• MLCK-activates phosphorylates MLC => cross bridge cycling
• Contraction halted by dephosphorylation of MLC by MLC phosphotase
• cAMP causes relaxation of VSMCs

Question 11

Describe the mechanisms by which sympathetic stimulation (via alpha1- adrenergic receptors) alters vascular tone

Answer 11

• These are GPCRs coupled to G(q)
• Gaq activates phospholipase C (PLC) => activates DAG and IP3
• IP3 activates IP3Rs (intracellular Ca++ release channels) on SR of VSMCs
• ^ Ca++ => VSMC contraction and vasoconstriction
• PKC phosphorylates targets in VSMCs (e.g. L-type Ca++ channels)

Question 12

What are arterial baroreceptors?

Answer 12

• Pressure sensitive neurons in aortic arch and carotid sinus
• Na+ channels open in response to mechanical stimulation (stretched by high BP) => Na+ depolarization => APs
• Baroreceptor neurons project to sensory area of CV control center in brainstem
• Distinct output areas control symp and parasymp output to heart and vasculature

Question 13

Describe the arterial baroreceptor reflex arc

Answer 13

• when stimulated by ^ BP => ^ baroreceptor firing rate => decreased sympathetic output and ^ parasymp
• This decreases HR, inotropy, and vascular tone => vasodilation and decreased BP

Question 14

What are the 4 tissue metabolites that control local flow to a capillary bed?

Answer 14

1) Decreased PO2
2) ^ PCO2/decreased pH
3) ^ K+
4) ^ Adenosine

Question 15

Describe the myogenic response

Answer 15

• Feedback mechanism designed to maintain constant flow despite pressure changes
• Intrinsic in VSMCs — Stretch causes VSMC contraction by opening stretch-activated ion channels => depolarize VSMC
• This ^ intracellular Ca++ via L-type

Question 16

Describe how nitric oxide regulates vascular smooth muscle tone

Answer 16

• NO increased vasodilation
• Mechanism: NO activates guanylate cyclase => ^ cGMP => activates PKG => decreases intracellular Ca++ via activation of SERCA & inhibition of L-type => Decreased Ca++ => relaxation and vasodilation

Question 17

Describe how endothelin regulates vascular smooth muscle tone

Answer 17

• Endothelin increases vasocontriction
• Produced by vascular endothelium
• mechanism: binds to ET receptors => GPCRs coupled to G(q) => similar to alpha-adrenergic response

Question 18

Describe the origin and effects of atrial natriuretic peptide on blood pressure

Answer 18

• ANP is a vasodilator => released by atria after mechanical stretch
• Involved in long-term Na regulation and H2O balance, blood volume, arterial pressure
• Acts on ANPRs (receptor guanylate cyclases) throughout body => produce cGMP => activates SERCA

Question 19

Describe the renin-angiotensin-aldosterone system

Answer 19

System for blood volume regulation

mediated by kidney

Question 20

Describe renin in the renin-angiotensin-aldosterone system

Answer 20

• released into circulation by juxtoglomerular cells when stimulated by JG cells, decreased BP in renal a., or decreased Na reabsorption in kidney
• Renin cleaves angiotensinogen to angiotensin I (AI)
• AI then cleaved by ACE to AII

Question 21

Describe the direct effects of angiotensin II

Answer 21

AII is a potent systemic vasocontrictor

Binds to GPCRs on VSMCs

Question 22

Describe the indirect effects of angiotensin II

Answer 22

1) Stimulates sympathetic activity => ^ vasocontriction
2) ^ aldosterone release from adrenal cortex
3) Stimulates endothelin release from vascular endothelium => ^ vasocontriction
4) stimulates ADH release from pituitary

Question 23

Describe aldosterone

Answer 23

• promotes Na and H2O reabsorption in the kidney

- This ^ blood volume => ^ BP

Question 24

Describe anti-diuretic hormone

Answer 24

• formed in hypothalamus
• released by pituitary
• ^ H2O reabsorption in kidney
• ^ peripheral vasoconstriction during systemic shock