3-5

Question 1

Define Homeostasis

Answer 1

The maintenance of relatively constant conditions in the body by physiological processes that act to counter any departure from the normal

Question 2

Who first used the term homeostasis

Answer 2

Walter Bradford Cannon

Question 3

Which variables are controlled in mammals

Answer 3

1) core body temperature
2) Osmotic Pressure
3) Arterial blood pressure 4) extracellular fluid volume
5) Blood gas concentrations
6) Concentrations of extracellular solutes like Na+, K+, and protons

Question 4

What is a conformer

Answer 4

An organism who do not complete active homeostasis as they have the same components as surroundings
- Hag fish

Question 5

Regulators?

Answer 5

GRAPH

Homeostatic organims

Question 6

Poikilothermy

Answer 6

An organism that does not regulate it’s own internal temperature—> Naked Mole rat

Question 7

How is homeostasis usually maintained

Answer 7

Negative feedback loops

Question 8

Positive feedback examples

x 3

Answer 8

Urination
Parturition
Metamorphosis

Question 9

How does negative feedback work

Answer 9

• Disturbance affects controlled system
• Sensor picks up difference
• Inverting amplifier
• Response which affects the controlled system

Question 10

What are the main sensors for negative feedback loops in mammals
x 5

Answer 10

1. Thermoreceptors (skin and hypothalamus)
2. Osmoreceptors (hypothalamus)
3. High pressure baroreceptors (carotid sinus, aortic arch and afferent arteriole of kidney)
4. Low pressure baroreceptors (atria, great veins and pulmonary vasculature)
5. Chemoreceptors (medulla oblongata and carotid and aortic bodies)

Question 11

What are neurocrine transmitters

Answer 11

Substances released by neurones in the immediate vicinity of target cells or into the blood—>neurotransmitters are a subset of this group

Question 12

Endocrine transmitters

Answer 12

Hormones

1) Synthesised by a specific tissue
2) Secreted into the bloodstream
3) Change the activity of that target tissue or organ

Question 13

Paracrine transmitters

Answer 13

‘local hormones’
Diffuse through extracellular fluid to reach and affect target cells of a different cell type to itself
Histamine and Nitric oxide

Question 14

Autocrine transmitters

Answer 14

Like paracrine but act on same cell type as those that secrete them

Question 15

Cytokines

Answer 15

Transmitters released by immune cells

Question 16

Pheromones

Answer 16

Released by animal into environment to affect physiology or behaviour of another animal of the same species

Question 17

Water-soluble hormones

explain and 3 types

Answer 17

Stored in vesicles and released by exocytosis—>travel loose in blood and bind to membrane-based receptors

TYPES

1) Peptide/ protein hormones
2) Glycoproteins
3) Catecholamines (derived from tyrosine)

Question 18

Lipid-soluble hormones

what and 4 types

Answer 18

Diffuse out of cells once made and transported in blood bound to special carrier proteins. Usually intracellular receptors

1) Steroid hormones
2) Thyroid hormones
3) fatty acid derivatives
4) Indolamines (melatonin)

Question 19

G-protein coupled receptor

Answer 19

GRAPH

Question 20

How to deactivate g-protein coupled receptor

Answer 20

Upon hydrolysis of GTP to GHDP on α-subunit will cause it to rebind to βγ-subunit and become inactive
- in cell a phosphodiesterase hydrolyses cAMP and terminates cell response

Question 21

Lipid-soluble hormone receptors

Answer 21

Usually in cells and act directly as transcription factors

Question 22

Getting rid of chemical messengers and half-lives

Answer 22

Most hormones metabolised by liver or kidneys

Half-lives of hormones in plasma can vary from 1-3 minutes for adrenaline to 7 days for thyroxine (T4)

Question 23

Blood-brain barrier

Answer 23

Prevents circulating substances which also act as neurotransmitters from acting on the brain

• its formed of endothelial cells being connected by particularly tight junctions
• held there by glial cells foot processes

Question 24

Where is the blood-brain barrier ‘leaky’

x4

Answer 24

1. Posterior pituitary gland
2. Median eminence
3. Pineal gland
4. Circumventricular organs

• fenestrated BBB so release hormones into blood or detect their presence

Question 25

Where is the hypothalamus

Answer 25

Small region of the forebrain above the pituitary gland

Question 26

What does the hypothalamus do?

Answer 26

Received input from many sources relating to both internal and external environment
—integrates information and controls physiological response—>homeostatic control centre

Question 27

The hypothalamus contains multiple intercommunicating nuclei

Answer 27

These are collections of nerve bodies

Question 28

Leptin example

intro

Answer 28

Protein hormone secreted by white fat cells and detected in arcuate nucleus of hypothalamus.

Use levels to establish body’s nutritional state

Question 29

What if leptin levels are high?—so well fed

Answer 29

1) Feeding behaviour suppressed
2) Release for TRH
3) activates hypothalamic-pituitary-thyroid axis—>increase metabolic rate
4) other function regulated reproductive axis in women

Question 30

Posterior pituitary

Answer 30

Downgrowth of the brain made of bundles of axons of nerve cells whose bodies are in the hypothalamus

Question 31

Anterior pituitary

Answer 31

Originates from Rathke’s pouch and lies outside of the BBB—>produces hormones

Question 32

ADH

Answer 32

Released from PP

• release at high osmotic pressure and in lower concentrations when there is low blood volume
  1) Acts on kidney collecting ducts to increase water permeability
  2) at higher concentrations causes vasoconstriction and compensates for loss of blood volume

Question 33

Oxytocin

Answer 33

released by PP

mainly in reproductive functions like the fergusson reflex
(where stretch of cervix then causes more contractions to push baby out, expanding cervix more)

Question 34

What is a portal vein

Answer 34

A vein that travels between two capillary beds

Question 35

Anterior pituitary hormones

Answer 35

Involved mostly in control of endocrine glands elsewhere in the body

1) Glycoproteins
2) Somatomammotropins
3) Pro-opiomelanocortin

Question 36

Hypothalamic-pituitary-thyroid axis

Answer 36

Hypothalamus send hormones to AP which cause release of another hormone which causes an endocrine gland (like thyroid) to release another hormone

—one of the jobs of this hormone is to inhibit the releasing hormone from hypothalamus=LONG-LOOP FEEDBACK
Short is from AP hormone inhibit hypothalamus and ultrashort is hypo prevents hypo

Question 37

TPT example

Answer 37

GRAPH

Question 38

Pulsatility

Answer 38

The releasing of hormones in bursts to prevent receptor down-regulation

Question 39

Feed-forward control

Answer 39

A mechanim by which to prevent ‘overshooting’ the set point and requiring negative feedback to go the other way
- like in drinking

Prevents oscillating levels

Question 40

What is dynamic equilibrium

Answer 40

Where there is no net force acting across a membrane as the concentration gradient is equal to the electrical gradient.
Represented by E (subscript of the ion)

Question 41

Why do we say that concentration stays roughly constant

Answer 41

very few ions move across membrane before dynamic equilibrium

Question 42

What is the Nernst equation?

at 20 degrees

Answer 42

E (ion) in mV = (58/z) log10(conc ion out/conc ion in)

Question 43

what does it mean if the membrane potential does not equal the equilibrium potential of one ion

Answer 43

Then the membrane is permeable to more than one ion

Question 44

Line predicted by the GHK equation fits the resting membrane potential of frog muscle cells than the line predicted by nernst K

What is the GHK equation

Answer 44

Picture

Question 45

What does P represent in the GHK equation?

goldman-Hodgkin-katz

Answer 45

The relative permeability of the ion

Question 46

What is ouabain

Answer 46

• toxin
• binds to sodium pump
• stops from working
• small loss of -5mV at first
• then slow to zero

Question 47

What is the actual name of the sodium pump

- what does it do

Answer 47

Sodium-potassium ATPase

• pumps out 3Na+ with 2K+ into the cell
• requires ATP

Question 48

role of sodium pump

Answer 48

Maintain the concentration gradients of sodium and potassium over long term and the slow leaking increases the concentration of sodium in the cell

Question 49

How to change membrane permeabilities to ions

Answer 49

Open more channels specific to that ion