Signal. Transduction

Question 1

What are the main purposes of cell- cell signaling and communication?

Answer 1

Key role in cellular processes such as proliferation, growth, differentiation, cellular mechanism and results in a variety of cellular responses

Regulation of:

• Gene 3xpression
• Metabolism
• Cell shape and cellular mechanism
• Neuronal signaling

Mis-regulating if signal transduction pathways:

• Cellular transformation (carcinogenesis)
• Endocrine disorders like diabetes mellitus, thyroid disorders

Question 2

Summarize metabolism Regulation

Answer 2

Metabolic pathways coordinated to produce of energy or synthesize products to meet needs of cell and organism

Efficient communication system necessary to coordinate various functions

Regulation depends on:

• Intercellular signals
• Intracellular signals

Question 3

Outline chemical(intercellular signals)

Answer 3

1. Secretion stimulus
2. Diffusion/receptor binding
3. Diffusion into the cell

Question 4

Compare intracellular vs cell-surface (plasma membrane) receptors

Answer 4

• Plasma membrane receptors have extracellular binding domains for ligand binding
• Intracellular receptors bind lipophilic/hydrophobic (steroid hormones or other messengers ) that diffuse through plasma membrane

-Intracellular receptors present in
-Cytoplasm and translocate to the nucleus on binding to hormone
OR
-Nucleus and hormone receptor complex binds tonDNA

Question 5

Describe cell surface receptors

Answer 5

• Hormone is hydrophilic
• Extracellular domain for binding hormone/signal
• Intracellular domain fir signal transduction
• Many produce second messengers within cells
• Rapid response; slower response effect
• Examples: Peptide hormones-insulin, glucagon, epinephrine, Acetylcholine; GABA; Eicosanoids

Question 6

Describe Intracellular receptors

Answer 6

• Lipophilic/hydrophobic signals diffuse through plasma membrane
• Located in nucleus or cytosol
• Conformational change on binding hormone
• H-R Complex enter nucleus
• Bind to specific regions of DNA
• Influence transcription and translation (gene expression)
• Function like transcription factors
• Response is slower
• Steroid hormones, thyroxine, retinoids acid (Vit. A) and vitamin D

Question 7

How can intercellular signals be converted to intracellular signals?

Answer 7

These are converted to an intracellular signal in the adjacent cell

Many extracellular signals (hormones) exert their effects by producing intracellular second messengers

Question 8

What are the intercellular signals?

Answer 8

Endocrine- hormones(insulin, glucagon, epinephrine, steroid hormones, peptide hormones)

Paracrine. Neurotransmitters, some growth factors, eicosanoids, nitric oxide(gas)

Some growth factors( eicosanoids) —> autocrine

Question 9

What are neuronal and contact signaling?

Answer 9

Neuronal- from nerve to target cell is synapse

Contact -cell signaling across gap junctions

Question 10

Describe specificity as a feature of intracellular signal transduction (receptor mediated)

Answer 10

A) specificity- signal molecule fits binding site on its complementary receptor; other signals don’t fit

Each hormone has specific receptors

A hormone may have more than one receptor line epinephrine and norepinephrine have slpha1, 2nand beta receptors (different tissues)

Acetyl choline has muscuranic and nicotinic receptors

Question 11

Describe amplification as a a feature of intracellular signaling mechanism

Answer 11

When enzymes activate enzymes of affected molecules increases geometrically in an enzyme cascade

Question 12

Describe the features of desensitization/adaptation

Answer 12

Receptor activation triggers a feedback. Circuit that. Shuts off the receptor or removes it from cell surface

Question 13

Describe integration as a feature of intracellular signal transduction

Answer 13

When two signals have opposite effects on aa metabolic characteristic such as the concentration of a second messenger X, or the membrane potential Vm, the regulatory outcome results from the integrated input from both receptors

“Outcome” is additive

Question 14

What are the 4 basic types of signal transduction pathways mediated by 4 different types of receptors?

Answer 14

1. Intracellular receptor (steroid receptor)
2. Gated-ion channel
3. receptor enzyme (catalytic channel)
4. Receptors that form intracellular second messengers

Question 15

Summarize the 4 general types of signal transducers

Answer 15

1. Steroid receptors- steroid binding to a nuclear receptor protein allows the receptor to regulate the expression of specific genes
2. Gated ion channel-opens or closes in response to concentration of signal ligand (S) or membrane potential
3. Receptor enzyme- ligand binding to extracellular domain stimulates enzyme activity in intracellular domain
4. Serpentine receptor- external ligand binding to receptor (R) activates an intracellular GTP-Binding protein (G), which regulates an enzyme (Enz) that generates an intracellular second messenger,X—> GPCR

Question 16

Explain steroid and thyroid receptor family (intracellular)

Answer 16

Lipophilic hormones cross cell membrane to bind specific intracellular receptors

Examples include: testosterone, estrogen, cortisol, aldisterone (steroid hormone)

• Vit. D and ergonomic acid (Vit a )
• thyroid hormone (thyroid receptors)

Hydrophobic/Lipophilic hormones induce (Up-regulate) or repress/down-regulate gene expression at level of transcription

Question 17

How do steroid-thyroid receptor family operate?

Answer 17

1. Bind intracellular receptors
2. Change in expression of target genes
3. Increased production of protein (induction) or repression

Question 18

Explain the functioning of steroid receptor signal transduction

Answer 18

-Hormone diffuses inti cell (Lipophilic/hydrophobic)

• Binds specific receptor (cytosol or nucleus)
  
  • forms hormone-receptor complex; conformational change in receptor
• H-R complex enters nucleus
• H-R complex binds specific regions of DNA (hormone response elements (HRE)
• H-R complex binds enhancer regions, activates promoter, increases transcription (INDUCTION of gene expression) and translation to form protein —> cellular response
• If H-R complex binds repressor regions —> decreased transcription (repression of gene expression)

Question 19

Outline steroid receptor signal transduction

Answer 19

• Binding of hormone receptor complex to HRE regulates expression of adjacent genes
• Increase or decrease rates of mRNA synthesis (transcription)
• Cause INDUCTION or REPRESSION of gene expression
• Works through modulating gene expression
• Hormone-Receptor complex works like a transcription factor
• Comparatively slow: response may take hours to days to be effective

Question 20

How long does steroid receptor signal transduction. Take?

Answer 20

Works through gene expression

Comparatively slow; response may take hours or days

Question 21

Outline ligand gated ion channels

Answer 21

• Binding of neurotransmitter causes channel to open
• Results in influx of ions through ion channels
• Alters membrane potential —> promotes or inhibits. Nerve impulse transmission

Some examples:
Nicotinic ACh receptors in parasympathetic ganglia and neuromuscular junction (muscle)

Glutamate receptors (lonotropic) in CNS

GABA-A receptors in CNS

Glycine receptors in CNS

Question 22

Outline gated ion channels

Answer 22

• parasympathetic ganglia (autonomic nervous system)
• neuromuscular junction(muscle)

Nicotinic Acetyl choline receptors

There is a conformational change on binding to Acetyl choline

Question 23

How is acetylcholine terminated?

Answer 23

Enters synaptic cleft or neuromuscular junction-signal is given

Cleaved by acetylcholine esterase (an enzyme)

Acetate and choline May be recycled

Question 24

What are the receptor enzyme(catalytic receptor) mechanisms ?

Answer 24

Transmembrane catalytic receptors have intrinsic enzymatic activity

Enzyme is tyrosine-specific protein kinase (adds P to tyrosine)

Insulin receptor

• Extracellular domain for binding insulin
• Intracellular domain with tyrosine kinase activity

Binding of ligand (insulin)—> ATP cleavage and autophosphorylation of tyrosine residues insulin receptor tyrosine kinase (IR) —> and then phosphorylation of specific tyrosine side chains in target proteins

Question 25

Summarize extracellular and cytoplasm activities of receptor enzyme

Answer 25

Extracellular, insulin binds

Insulin receptor activated, in the cytoplasm, ATP is then used to phosphorylates the IR on the cytoplasmic side of the IR

Activation of tyrosine kinase domains of IR by insulin binding, followed by autophosphorylation

Question 26

What are the intracellular insulin receptor effects ?

Answer 26

• Intracellular effectors:
  
  • Insulin receptors substrates: IRS 1-4
  • Enzyme effectors: activation of PI3-kinase
  • Multiple signaling pathways
• Cellular responses:
  
  • Increased glucose uptake
  • Regulation of transcription
  • Activation of enzymes and regulation of metabolism
    
    • Covalent modification
    • Upregulation (increased synthesis of enzymes)

Question 27

How does insulin stimulate glucose transport (GLUT-4) in adipose or muscle cells?

Answer 27

1. Insulin binds to its receptor
2. GLUT 4 translocation from Golgi to plasma membrane
3. Vesicle containing GLUT 4 binds and fuses to plasma membrane
4. Glucose transport allowed in response to insulin
5. Insulin dissociates from receptor; inactivation
6. Vesicle containing GLUT 4 trans located back to Golgi

Question 28

The insulin receptor is a …

Answer 28

Dimer with two different types of subunits . It spans the membrane

Question 29

Describe the subunits of insulin receptors

Answer 29

The B-subunits are tyrosine kinases. When insulin binds the subunits phosphorylate themselves at tyrosine residues.

The subunits also phosphorylate other protein kinases at tyrosine residues. These kinases produce the cellular responses

Question 30

What receptors that form second messengers?

Answer 30

-Receptors pass signal (message) from outside cell by produc8ng sound messenger inside the cell

Types of receptors

• G protein coupled receptors
• Guanylate cyclase (cGMP)

Rapid and immediate effects

• Phosphorylation of enzymes (activation or inactivation of key regulated enzymes)
• Changes in ion levels (calcium)

Slower effects on gene expression

Covalent modification of enzymes

Question 31

Outline G-protein coupled receptors and intracellular second messengers

Answer 31

• Hormone (first messenger) changes concentration of some other molecule (second molecule) inside the cell
• Generally small, non- protein molecules
• produced intracellular LH when hormone binds to its receptor
• Initiate cascade of intracellular events (enzyme activation/inhibition, altered gene regulation ) resulting in specific cellular responses

Example:

• Adenylate cyclase system produces cAMP
• Calcium- phosphatidylinositol system produces IP3, DAG, Ca2++

Question 32

Summarize GPCR’s( G-protein coupled receptors), heptahelical receptors and second mass angers

Answer 32

The extracellular domain contains the binding site for a ligand (a hormone or neurotransmitter)

Intracellular domain that interacts with G-proteins

Seven transmembrane helixes

Question 33

Summarize the heptahelicalreceptors GPCR’s and second messengers.

Answer 33

• Hormone (or cytokine or neurotransmitter) is first messenger
• Binds plasma membrane heptahelical receptors
• Hormone- receptor complex activates G-protein that activates membrane-bound enzyme (effector enzyme)
• Activation of different GPCRs lead to generation of different intracellular second messengers such as cAMP or DAG/IP3

Question 34

What are heterotrimeric G proteins?

Answer 34

• Binding of hormone to receptor activates G protein
• The Galpha-subunit dissociates; binds GTP (Ga-GTP) is active
• Ga-GTP activates enzymes to produce intracellular second messengers
• Ga subunit has intrinsic GTPase activity (intrinsic timer)-termination of signal

Question 35

What are the types of Ga ?

Answer 35

Alpha 1 adrenergic receptor: Gaq

• activates Phospholipase C
• Increases IP3, DAG, Ca2+(second messengers)

Alpha 2 adrenergic receptors(inhibitory) Gai:

• Inhibits Adenylate cyclase
• Decreases cAMP levels

Beta-adrenergic receptors; glucagon (stimulatory) : Gas:

• Activates Adenylate cyclase
• Increases cAMP levels