FORM & FUNCTION (Signalling)

Question 1

types of signal transmission

Answer 1

1. Direct: cells are connected
   >gap junctions
   >contact-dependent
2. Indirect: cells are not connected
   >Paracrine
   >hormonal

Question 2

gap junctions (direct)

Answer 2

-epithelial cells
-heart muscle and smooth muscles
-essentially all tissues where cells touch each other

Question 3

contact-dependent (direct)

Answer 3

-juxtacrine signalling
-cells NEED to make direct physical contact through a signal molecule on the PM
-important during embryonic development
>allows adjacent cells to differentiated into a different cell-type

Question 4

paracrine signalling

Answer 4

-signals are transmitted in the interstitial fluid (diffus locally through extracellular fluid)
-only nearby cells are affected
Ex. inflammation, wound healting

Question 5

paracrine signalling types

Answer 5

-autocrine
-between neurons

Question 6

autocrine

Answer 6

-type of paracrine signalling
-cells respond to local signal produced by themselves
-important in development where cell gets its own signal to develop into correct tissues
Ex. interleukins released by T-helper cells can signal themselves to self-amplify

Question 7

neural signalling

Answer 7

-type of paracrine signalling
-can travel far
-very fast (in ms)
-affect post synaptic neurons
-signals can be released into the blood stream (neuroendocrine)

Question 8

hormonal signalling

Answer 8

-hormones released by endocrine cell
-signal molecules travel in blood stream to target cells
-not ver fast, but more FLEXIBLE since signals can affect they cells that express the receptors

Question 9

hormonal signalling receptors

Answer 9

-must have a very high affinity for the hormon as hormones get diluted in blood

Question 10

type of signal molecules

Answer 10

1. Lipid-insoluble
2. Lipid-soluble
3. Gaseous-cardiovascular
4. Intracellular messengers

Question 11

lipid-insoluble

Answer 11

-amino acids (glutamate, aspartate)
-modified amines (biorgenic amines)
-peptides/proteins (less than 50AA)
-non-coding RNA

Question 12

modified amines (lipid-insoluble)

Answer 12

1. Tyrosine: catecholamines
   -dopamine
   -NE (primary NT of post synaptic neurons in SNS)
   -E (sympathetic hormone)
2. Histamine (from histidine)
3. Serotonin (from tryptophan)

Question 13

lipid soluble

Answer 13

1. Biogenic amine (modified AA): thyroid
2. Steroids (estradiol, testosterone, cortisol)
3. eicosanoids

Question 14

eicosanoids

Answer 14

-made from arachidonic acid (component of PM) from 2 pathways
1. Cyclooxygenase (COX) pathway
2. Lipoxygenase pathway

Question 15

cyclooxygenase (COX) pathway

Answer 15

-prostaglandins
-prostacyclins
-thromboxanes

Question 16

lipoxygenase pathway

Answer 16

-leukotrienes

Question 17

Gaseous

Answer 17

Nitric oxide
-released by endothelial cells causes smooth muscles to relax=leads to vessel dilation=increase blood flow
-does not need a membrane transporter on the target cell

Question 18

intracellular messengers

Answer 18

-cAMP
-IP3
-Diacylglycerol (DAG)
-Ca2+

Question 19

target cell responses

Answer 19

-depend on chemical properties of signal molecules
-bind to either extracellular or intracellular receptor

Question 20

extracellular receptor

Answer 20

-lipid-insoluble signal molecules

Question 21

intracellular resceptor

Answer 21

-lipid-soluble molecules
-cytosolic or nuclear

Question 22

intracellular receptor cortisol

Answer 22

-steroid hormone
-regulates stress response, metabolism and immune regulation

Question 23

Cortisol intracellular receptor steps

Answer 23

1. Diffuses through PM and binds to receptor in cytosol
2. Cortisol/receptor complex moves into nucleus and activates target genes important in metabolism, immune responses, and stress adaptation

Question 24

3 classes of cell-surface receptors

Answer 24

1. ion-channel coupled receptors
   -ligand gated channels
2. Enzyme coupled receptors
3. G-protein coupled receptors (GPCR)

Question 25

Ion-channel coupled receptor (NMJ):

Answer 25

-nicotinic receptor at neuromuscular junction
1. Ach release from the motor neuron
2. Ach binds to nicotinic receptor on muscle fiber
3. Ion channel opens and allows sodium ions to move (will move out of the cell)

Question 26

Enzyme-coupled receptor (insulin receptor)

Answer 26

-tyrosine kinase (adds P group)
1. Insulin binds and activates receptor (triggers dimerization and autophosphorylation)
2. The activation recruits and activates other intracellular proteins for cellular response
3. Translocation of glucose transporters to cell membrane (allows cells to uptake glucose from blood stream)

Question 27

GPCR

Answer 27

-trimeric G-protein is the first molecular switch
-activated G-protein: when GDP on alpha subunit is turned to GTP

Question 28

GPCR ‘steps’

Answer 28

1. Directly open a channel
2. Activate an enzyme that generates second messengers to amplify primary response
   >adenylyl cyclase generates cAMP
   >phospholipase C generates IP3, diacylglycerol (DAG) and Ca2+

Question 29

Phosphodiesterase

Answer 29

-a common drug target
-degrades cAMP

Question 30

Fight or flight response: SNS

Answer 30

1. Trigger
2. Primary signals
3. Key targets
4. Immediate effects
5. Metabolic changes

Question 31

SNS trigger

Answer 31

-perception of threats or stressor

Question 32

SNS primary signals

Answer 32

-release E(adrenaline) and NE

Question 33

SNS key targets

Answer 33

-heart
-lungs
-muscles
-other crucial systems

Question 34

SNS immediate effects

Answer 34

-increase heart rate
-elevate BP
-redistribute blood flow to essential organs and muscles

Question 35

SNS metabolic changes

Answer 35

-breakdown of glycogen to glucose for rapid energy supply

Question 36

E binding to adrenergic receptor on skeletal muscle cell

Answer 36

1.E binds to adrenergic receptor (GPCR)
2.Triggers activation of G protein
3.G protein activates adenylyl cyclase that converts ATP to cAMP
4.cAMP (second messenger) activates a series of proteins leading to glycogen breakdown
5.Physiologically this provides more glucose more muscle cell to generate ATP for muscle contraction

Question 37

GPCR that activates phospholipase C to generate IP3, DAG and Ca2

Answer 37

1.NE binds to alpha-1-adrenergic receptor on smooth muscle around blood vessels
2.Alpha-1 adrenergic receptors are GPCRs that activate PLC
3.Activated PLC cleaves inositol phospholipids to IP3 and DAG
4.IP3 binds to ER receptors, triggering calcium release from ER
5.DAG, along with increased calcium, activated protein kinase C (PKC)
6.PKC phosphorylates other proteins, *promotes smooth muscle contraction=vasoconstriction=increased BP

Question 38

rest and digest: PNS

Answer 38

1. Primary signals
2. Key targets
3. Immediate effects
4. Metabolic changes

Question 39

PNS primary signals

Answer 39

-Acetylcholine (acetyl-CoA and choline)

Question 40

PNS key targets

Answer 40

-heart
-lungs
-muscles
-other crucial systems

Question 41

PNS immediate effects

Answer 41

-restore heart rate
-restore BP
-redistribute blood to all organs

Question 42

PNS metabolic changes

Answer 42

-promote glycogen storage and nutrient absorption

Question 43

Ach activates GPCR on heart cells

Answer 43

1. Ach activates GPCR on heart cells
2. Activated Gbeta-gamma complex opens K+ channel
3. K+ movement leads to a decrease in HR (move inside to outside cell)

Question 44

Cellular response variability

Answer 44

-can be fast or slow
-same signalling molecule can bind to different receptors and cause different responses

Question 45

signalling molecule can bind to different receptors and cause different responses (Ach examples)

Answer 45

1. Heart pacemaker: decrease rate of firing
2. Salivary glands: secretion
3. Skeletal muscle: contraction