Signal Transduction and Secondary Messengers Mahmoud Farhat.
Chapter 14. Signal Transduction Signal transduction is the process by which an extracellular signal...
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Transcript of Chapter 14. Signal Transduction Signal transduction is the process by which an extracellular signal...
Chapter 14. Signal Transduction
Signal transduction is the process by which an extracellular signal alters intracellular events.
1. First and second messengers.1) First messengers: refer to the extracellular
signaling molecules, including neurotransmitters, hormones, and local mediators.
A) Neurotransmitters (synaptic signal): secreted by neurons and diffuse to target cells causing physiological response such as muscle contraction.
Target cell
Axon
PostsynapticNeuron
Presynaptic
B) Hormones (endocrine signal): secreted by endocrine glands in trace amounts and transported by the bloodstream to target cells, causing physiological effects.
Target cell
Endocrine cell
Bloodstream
C) Local mediators: include growth factors and cytokines. They can be subdivided into autocrine and paracrine groups.
Autocrine group: extracellular signaling molecules secreted by autocrine cells act on the cells which released the substance.
Paracrine group: extracellular signaling molecules secreted by paracrine cells diffuse to and act on nearby cells.
Autocrine
Paracrine
2) Second messengers: refer to those molecules that mediate the action of the first messengers, such as cAMP, cGMP, Ca2+, inositol triphosphate (IP3), diacylglycerol (DAG).
One of the main functions of second messengers is to activate their cognate protein kinases. For instance, cAMP activates protein kinase A, cGMP activates protein kinase G, DAG activates protein kinase C, and Ca2+ activates Ca2+/ calmodulin protein kinases I, II, and III.
3) Receptors: are those molecules that are recognized and bound by first messengers. Receptors may be on the cell membrane or inside the cytosol. e.g. epinephrine binds to its receptor on the cell membrane causing activation of adenylate cyclase.
Inactive ad. cyclase
active ad. cyclase
ATP cAMP
Receptor
Epinephrine
2. Mechanisms by which cAMP mediates the action of hormones.
1) The receptors: are membrane proteins with a hormone-binding domain on the extracellular side, and a loop on the cytosolic side which participates in the activation of stimulatory G protein (Gs).
e.g. the -adrenergic receptor is a 64 kDa protein that spans the target cell membrane.
The -adrenergic receptor
Hormones that use cAMP as a second messenger
Calcitonin Corticotropin
Chorionic gonadotropin Epinephrine
Follicle stimulating hormone Glucagon
Luteinizing hormone Lipotropin
Thyroid stimulating hormone Parathyroid hormone
Norepinephrine Vasopressin
Melanocyte stimulating hormone
2) G proteins: are the guanyl nucleotide-binding proteins which hydrolyze GTP.
The G protein that controls adenylate cyclase is called “stimulatory G protein ”, or Gs.
Gs consists of three subunits: , , and . G-GTP is the active form while G-GDP is the inactive form. These two forms can change to each other triggered by exchange between GTP and GDP on the -subunit.
Active-inactive interconversion of Gs
Activation of adenylate cyclase mediated by Gs:
Hormone binds to the receptor activation of Gs (G-GTP) G-GTP diffuses and binds to adenylate cyclase activation of adenylate cyclase ATP is converted into cAMP.
After adenylate cyclase has been activated, G-GTP is converted into G-GDP, which then diffuses from adenylate cyclase and binds to G. The receptor is deactivated by phosphorylation
Activation of adenylate cyclase
cAMP stimulates phosphorylation of target proteins:
Most effects of cAMP are mediated by protein kinase A (PKA):
C C
R R
C C
R R
Inactive PKA Active Active
cAMP
cAMP
Activated PKA phosphorylates many target proteins to alter their activity, such as that in glycogen metabolism:
epinephrine
cAMP
ATP
PKA
Phosphorylase b kinase
Phosphorylase a
Glycogenolysis
receptor
3. Mechanisms by which inositol triphosphate (IP3) opens Ca2+ channels.
Hormone (e.g. vasopressin) binds to a cell-surface receptor activation of phospholipase C (PLC) production of IP3 and DAG.
IP3 binds to the membrane of intracellular Ca2+ stores (ER, sarcoplasmic reticulum in smooth muscle cell) opening of Ca2+ channels cytosolic [Ca2+].
DAG
PKC
PKC被激活
DAG
PKC
PKC activation
Hormone
Cytosolic [Ca2+] responses in the target cell, such as smooth muscle contraction, glycogen breakdown, and vesicle release.
DAG is also a second messenger, it activates protein kinase C (PKC) by increasing the affinity of PKC for Ca2+
phosphorylation of target proteins.
4. Mechanisms by which growth factors (GF) induce cell growth and differentiation.
1) Tyrosine kinase receptor: a membrane-spanning protein with an extracellular domain that is recognized and bound by GF, and a cytosolic domain with kinase activity.
2) Classes of tyrosine kinase receptors: type 1, 2, 3, 4 (such as epidermal GF receptor, insulin receptor, and platelet-derived GF receptor, and fibroblast GF receptor, respectively).
Classes of tyrosine kinase receptors
Cys
rich domain
Cytosol
EGF-R IGF-I-R
PDGF-R FGF-R
Tyrosin
e kin
ase
membrane
Type 1 Type 2 Type 3 Type 4
Antibody like dom
ain
3) Binding of growth factor to tyrosine kinase receptor causes phosphorylation of target proteins in the cell. The phosphorylated target protein in turn activates the genes through a series of reactions, leading to expression of the specific gene.
e.g. binding of EGF to EGF-R dimerization and autophosphorylation phosphorylation of target proteins response of the target cell (e.g. gene expression).
Mechanism of EGF receptoractivation
5. Mechanisms by which steroid hormones regulate expression of specific genes
Steroid hormones are lipophylic molecules that can enter into the target cells by diffusion.
Receptors of steroid hormones are located in the cytosol or nucleus
The hormone-receptor complex undergoes some changes in size, conformation, and surface charge.
The hormone-receptor complex then binds to a specific region of DNA (called the hormone response element, HRE) and activates or inactivates the specific genes.
Thyroid and retinoid hormones act by mechanisms similar to that of steroids.
6. Characteristics of receptor-mediated signal transduction
A) High specificity
B) High affinity
C) Saturable
D) Reversable
E) High efficiency
Plot of receptor-ligand interaction
Concentration of ligandSatu
ratio
n of
rec
epto
r(%
)