Second Messengers

Question 1

What are second messengers?

Answer 1

Molecules that relay signals received at receptors on the cell surface to target molecules in the cytosol and/or nucleus. In addition, second messengers serve to greatly amplify the strength of the signal

Question 2

Major classes of second messengers

Answer 2

• cyclic nucleotides (e.g. cAMP, cGMP)
• inositol triphosphate (IP3) and diacylglycerol (DAG)
• calcium ions (Ca2+)
• arachidonic acid (AA)

Question 3

Cyclic nucleotides

Answer 3

• cAMP and cGMP: derivatives of ATP and GTP respectively
• diffuse freely in cytoplasm, act by binding reversibly to specific target proteins
  
  • cAMP to protein kinase A
  • cGMP to protein kinase G
• inactivated by phosphodiesterases (break cyclic nucleotides to 5’monophosphates)

Question 4

Adenylyl cyclase

Answer 4

• 12 membrane spanning segments
• at least 8 isoforms known
• 2 catalytic domains
• calmodulin binding site is regulated by Ca2+
• 1 G protein activates 1 cyclase
• 1 cyclase produces 100-1000 cAMP

Question 5

Actions of cAMP

Answer 5

• activates Proetin Kinase A (phosphorylates ion channels, and enzymes) - rapid action
• activates cyclic nucleotide gated channels (CNGC, change membrane potential) - rapid action
• activates transcription factors and changes gene expression - slow action

Question 6

Signal transduction - cAMP-PKA

E.g. flight or fight response

Answer 6

Reception:
- Binding of adrenaline to beta receptor
Transduction:
- Inactive G protein is activated (G alpha s subunit dissociates)
- Inactive adenylyl cyclase becomes active adenylyl cyclase (one G protein activates one cyclase)
- ATP is converted to cAMP (one cyclase produces 100-1000 cAMP)
- Inactive phosphorylase kinase becomes activate phosphorylase kinase (increase by factor of 10)
- Inactive glycogen phosphoylase becomes active glycogen phosphorylase (increase by factor of 10)
Response:
Glycogenolysis: Glycogen produces glucose-1-phosphate (increase x100) which is converted to glucose-6-phosphate

Question 7

Signal transduction - cAMP-PKA

general

Answer 7

• G alpha s subunit
• increased adenylyl cyclase
• increased cAMP
• increased protein kinase A
• increased protein phosphorylation
• G alpha i subunit
• reduced adenylyl cyclase
• reduced cAMP
• reduced protein kinase A
• decreased protein phorphorylation

Question 8

Signal transduction - IP3/DAG

Answer 8

• G alpha q subunit
• production of phospholipase C
• IP3 and DAG production
• IP3 causes Ca2+ release, DAG causes protein kinase C production and AA production
• AA converted to eicosanoids (released as hormones)
• Ca2+ released and protein kinase C cause increased protein phosphorylation, activate calcium-binding proteins

Question 9

cAMP-PKA and cardiac muscle contraction

Answer 9

• ATP converted to cAMP, activating PKA causing Ca2+ influx, enters SR, causing increased Ca2+ efflux from SR leading to contraction

Question 10

cAMP-PKA and smooth muscle relaxation

Answer 10

Normal pathway:

• Ca2+ influx which combines with Ca2+ released from ER to form calmodulin (Ca2+)4 radical
• leads to myosin light chain kinase (MLCK)
  
  • when inactive smooth muscle relaxation occurs
  • when activate, myosin-(PO4)2 is produced leading to smooth muscle contraction
• when PKA is activated myosin light chain kinase signalling is inhibited, meaning the MLCK is not active, leading to smooth muscle relaxation

Question 11

cAMP-inducible gene expression - CREB

Answer 11

• cyclic AMP response element binding protein (CREB)
• CREB is a transcription factor which is activated by cAMP-dependent PKA
• CREB binds to certain DNA sequences called cAMP response elements (CRE)
• Genes with either (TGACGTCA) or (CGTCA) CRE motif in the promotor are activated by CREBS
• PKA consists of paired regulatory (R) and catalytic (C) subunits
• cAMP binds to the R subunits, leading to release of C subunits
• liberated C subunits migrate into the nuclear compartment by passive diffusion
• C subunits phosphorylate CREB
• Phosphorylated CREB promotes the recruitment of the co-activator CREB-binding protein, which in turn mediates transcriptional activation through association with RNA polymerase to regulate mRNA expression
• CREB is activated in response to a great array of physiological stimuli and is associated with numerous cellular functions

Question 12

Guanylate cyclase and cGMP

Answer 12

• nitric oxide
• cGMP activates protein kinase G
  • -> myosin phosphatase –> smooth muscle relaxation
  • -> VASP –> platelet inhibition
  • -> transcription factors –> changes in gene transcription

Question 13

IP3 and DAG

Answer 13

• G-alpha-q protein couples to phospholipase C (PLC)
• PLC is an enzyme that hydrolyses phosphatidylinositol 4,5-biphosphate (PIP2) to form inositol triphosphate (IP3 and diacylglycerol (DAG)
• DAG activates protein kinase C
• IP3 signals the release of Ca2+ ions from the ER stores

Question 14

PIP2

Answer 14

• PIP2 is a minor component of cell membrane, localised to the inner phospholipid layer
• cleavage of PIP2 by phospholipases produce various active mediators
• cleavage by PLA2 yields arachidonic acid
• cleavage by PLC yields IP3 and DAG
• cleavage by PLD produced phosphatidic acid (PA)

Question 15

IP3-Ca2+ and smooth muscle contraction

Answer 15

• G alpha q
• IP3 produced
• IP3 receptor activated, releasing Ca2+ from ER stores
• Ca2+ combine with Ca2+ ions that have influxed from extracellular stores to produce calmodulin radicals (Ca2+)4 which activated myosin light chain kinase
• causes myosin-(PO4)2 to be released
• leads to filament sliding muscle contraction

Question 16

Targets of IP3

Answer 16

Direct effects

• cell motility
• contraction of muscle cells
• secretion
• activation of regulatory enzymes
• Ca2+ activated K+ channels

Effects through calmodulin

• activation of phosphorylase kinase
• activation of cAMP phosphodiesterase

CaM kinase II: Calcium/calmodulin-dependent protein kinase II is a serine/threonine-specific protein kinase

Question 17

Calcium as second messenger

Answer 17

• Ca2+ very important in regulating cellular and physiological responses
• extracellular concentrations are 2mM (e.g. blood) and levels in cytoplasmic vesicles and the ER can reach up to 10mM
• Baseline cytosolic Ca2+ conc. is around 100nM in resting cells
• high gradient makes this a very fast and sensitive signalling system - only sligh changes in membrane permeability will result in dramatic changes in the concentration of [Ca2+]

Question 18

Sources of calcium - intracellular

Answer 18

Intracellular compartment (calcium is released from intracellular apparatus into the cytoplasm)

• Ca2+ is stored in mM concs. in ER and SR
• two types of calcium channels (IP3 receptors and ryanodine receptors) on the ER and SR membrane control the release of Ca2+ from these stores

Intracellular compartment: calcium release mechanisms

• IP3R - IP3 produced through receptor activated PLC pathway. IP3 diffuses through cytoplasm and binds IP3R. IP3R is a ligand-gated ion channel. No specific blocking agents for IP3R (heparin can be used by intracellular injection)
• Ryanodine receptors (RyR) - named after sensitivity to ryanodine. Very important in skeletal muscle - mediated Ca2+-mediated Ca2+ release. Also activated by cyclic ADP ribose. Activated by caffeine, blocked by ryanodine.

Question 19

Sources of calcium - extracellular

Answer 19

• voltage gated calcium channels
• ligand gated calcium channels
• store operated calcium channels
• sodium-calcium exchanger

Question 20

eicosanoids

Answer 20

• eicosanoids are a class of lipids including prostaglandins, prostacyclins, thromboxanes and leukotrienes, that acts in autocrine and pararcrine signalling
• prostaglandins and leukotrienes are important inflammatory mediators

PLC/PLA2 converts diacylglycerol or phospholipid to arachidonic acid (AA)?

Question 21

second messengers as drug targets

Answer 21

Erectile dysfunction

• glyceryl trinitrate is a NO donor, used in treatment of angina and ischaemic heart disease
• phosphodiesterase type 5 (PDE5) is found predominately in the corpus cavernosum
• PDE5 inhibitors (sildenafil, vardenafil, tadalafil) - first line drugs for males with erectile disfunction (potential for pulmonary hypertension)

calcium channel blockers

• main clinical use to treat hypertension
• some can also be used as anti-anginals