MBC - Cell Signalling

Question 1

What are the 4 needs for cell signalling?

Answer 1

1. Process information
2. Self preservation
3. Voluntary movement
4. Homeostasis

Question 2

Why do cells need to process information?

Answer 2

We send and receive millions of inputs with crucial information, with with or without output. Output means that the brain must coordinate a response with different organ subsets.

Question 3

What is an example of processing information?

Answer 3

Our eyes receive information that must be processed, giving us vision

Question 4

Why do cells need to self preserve?

Answer 4

Most innate/voluntary responses are generated from an input received by the brain.

Question 5

What is an example of self-preservation?

Answer 5

The spinal reflex arc with our fingers touching a hot flame or any other dangerous stimuli.

Question 6

Why do cells need to move voluntarily?

Answer 6

interdependency between a variety of different sensory and motor organs all coordinated by different parts of the brain.

Question 7

What is an example of voluntary movement?

Answer 7

Getting from A to B

Question 8

Why do cells need homeostasis?

Answer 8

Allow our body to function normally through involuntary actions

Question 9

What is an example of homeostasis in cells?

Answer 9

Blood sugar levels being regulated by the pancreas

Question 10

What are the 2 main modes of intercellular signalling?

Answer 10

Neurotransmission

Blood vessels of the cardiovascular system.

Question 11

What is neurotransmission?

Answer 11

Fast and almost instantaneous communication involving the PNS and CNS.

Question 12

What is the first step of neurotransmission?

Answer 12

Propagation of the axon potential due to the sodium potassium pump.

Question 13

What is the second step of neurotransmission?

Answer 13

NT release from vesicle, diffusion across the synaptic gap.

Question 14

What is the third step of neurotransmission?

Answer 14

Activation of post synaptic receptors

Question 15

How do blood vessels signal?

Answer 15

Blood vessels facilitate blood transport all over the body as well as the movement of chemical messengers known as hormones.

Question 16

What are the 4 main methods of blood vessel (hormone) communication?

Answer 16

Endocrine
Paracrine
Communication between membrane receptors (proteins)
Autocrine

Question 17

What is endocrine communication?

Answer 17

When hormones travel within blood vessels to act on a distant target cell/tissue

Question 18

What is an example of endocrine communication?

Answer 18

Glucagon from alpha cells in the pancreas, causing glycogenolysis and gluconeogenesis in the liver

Question 19

What is paracrine communication?

Answer 19

When a hormone acts on an adjacent cell

Question 20

What is an example of paracrine communication?

Answer 20

Insulin is secreted by B-cells in the islet of Langerhans to then act on adjacent A-cells and thus inhibit the secretion of glucagon.

Question 21

What is communication between membrane attached proteins?

Answer 21

Extracellular proteins act/induce effects in other cells through interaction with their different proteins or receptors.

Question 22

What is an example of communication between membrane attached proteins?

Answer 22

Blood borne virus being detected by antigen presenting cell.

This cell then expresses MHC II on surface to subsequently activate T lymphocytes via T cell receptors.

Question 23

What is autocrine communication?

Answer 23

Signalling when a molecule acts on the same cell

Question 24

What is an example of aubocrine communication?

Answer 24

Activated T cell receptor activates a cascade whereby interleukin-2 receptor is expressed on cell surface and IL-2 is secreted, thus allowing the cell to act upon itself

Question 25

What is the general overview of how receptors function?

Answer 25

Ligands bind to receptors, eliciting a reaction in the cell. This intracellular effect is usually due to a new chemical called the secondary messenger.

Question 26

What are the 4 categories of receptor?

Answer 26

G-protein coupled receptor
Intracellular receptor
Ligand gated ion channel receptor
Enzyme-linked receptor

Question 27

What is another name for G-protein coupled receptors?

Answer 27

7-transmembrane receptors as their protein channel crosses the membrane 7 times.

Question 28

Describe the structure of G-protein coupled receptors

Answer 28

Receptor is linked to G protein complex (heterorimer):

• Ga subunit divided into 3 physiologically variable categories
• Gby subunit which is physiologically active.
• GDP molecules

Question 29

What are the steps of ligand binding to G-protein coupled receptors?

Answer 29

Ligand binding causes the protein complex to become associated with the receptor due to a change in receptor conformation. This causes GDP to be phosphorylated to GTP.
Ga attached to GTP uses energy to dissociate from Gby and move into target cell.
Ligand dissociated - GTPase on Ga hydrolysis GTP to GDP, restoring previous state

Question 30

What are intracellular receptors?

Answer 30

Essentially transcription factors to control mRNA and protein synthesis

Question 31

How do steroid hormones bind to intracellular receptors?

Answer 31

Hydrophobic so pass through lipid bilayer membrane and bind directly to receptor in the cell.

Question 32

What are the sub categories of intracellular receptors?

Answer 32

Type 1

Type 2

Question 33

Where are type 1 intracellular receptors located?

Answer 33

Cytosol

Question 34

Where are type 2 intracellular receptors located?

Answer 34

Nucleus

Question 35

What associates with type 1 intracellular receptors?

Answer 35

Chaperon molecules - normally heat shock protein (hsp)

Question 36

What associates with type 2 intracellular receptors?

Answer 36

Bound to DNA

Question 37

How do type 1 intracellular receptors work?

Answer 37

ligand binding leads to hsp (chaperone) dissociation allowing for hormone receptor complex formation. Then binds with identical complex, forming homodimer which translocates into nucleus to regulate transcription

Question 38

How do type 2 intracellular receptors work?

Answer 38

Binding of the hormone ligand which can translocate into the nucleus and bind to DNA to regulate transcription

Question 39

What is another name for ligand gated ion channel receptors?

Answer 39

Ionotropic receptors

Question 40

Describe the structure of ligand gated ion channel receptors?

Answer 40

Quaternary structure with ligand binding domain on external surface and a central pore located on the inside of the structure

Question 41

How do ligand gated ion channel receptors work?

Answer 41

Ligand binds to domain to cause conformational change and lead to opening of central pore. This allows facilitate diffusion of ions such as sodium, potassium and calcium.

Question 42

How do ligand gated ion channel receptors differ?

Answer 42

Different receptors have different ligands which will lead to different effects upon activation.

Question 43

What is an example of ligand gated ion channel receptors?

Answer 43

Nicotinic Ach receptor binds to Ach, facilitating skeletal muscle contraction and cognitive neuronal enhancement.

Question 44

What are enzyme linked receptors?

Answer 44

Transmembrane receptors consisting of only one domain to which a ligand binds.

Question 45

How do enzyme-linked receptors work?

Answer 45

1. Binding of the ligand to each receptor leads to receptor clustering and thus activating intracellular enzymes (kinases)
2. Enzymes phosphorylate receptor to activate it
3. Activation causes signalling proteins to bind to cytoplasmic domain
4. Signalling proteins recruit other signalling proteins and generate a signal within the cell