Tissues 2

Question 1

Name the 4 cerebral hemispheres and locate them

Answer 1

Frontal, Temporal, Parietal, Occipital

Question 2

Name the convoluted ridges of the brain

Answer 2

Gyri are the ridges

Sulci are the grooves

Question 3

What is the brainstem composed of

Answer 3

Midbrain, pons and medulla

Question 4

What is the function of the brainstem

Answer 4

Target source of all cranial nerves with numerous functions

Question 5

Locate the cerebellum and give its function

Answer 5

Hindbrain attached to the brainstem

Motor coordination, balance and posture

Question 6

What is the function of the spinal cord

Answer 6

Conduit for neural transmission

Co-ordinates some reflex actions

Question 7

Outline the following:
Unipolar
Pseudo-unipolar
Bipolar
Multipolar

Answer 7

Unipolar - 1 axonal projection (Rare)
Pseudo-unipolar - single axonal projection dividing into 2
Bipolar - 2 projections from the cell body
Multipolar - numerous projections from the cell body (only 1 axon)

Question 8

Give 3 examples of multipolar neurones

Answer 8

pyramidal
Purkinje
Golgi

Question 9

Describe astrocytes

Answer 9

Most abundant in the CNS
Able to proliferate
Neuroglial

Question 10

What are the functions of astrocytes

Answer 10

Structure
Cell repair
Immune cells
Neurotransmitter release and re-uptake

Question 11

Describe an oligodendrocyte

Answer 11

Variable morphology and function
Numerous projections that form internodes of myelin
Myelinates axons

Question 12

What is the function of Schwann cells

Answer 12

Produces myelin for peripheral nerves

Question 13

What is the function of Microglial cells

Answer 13

Immune functions in the CNS

Question 14

What is the function of ependymal cells and where is it found

Answer 14

Regulates the production and movement of cerebrospinal fluid. Found lining fluid filled ventricles

Question 15

Explain the process of intracellular communication through a synapse

Answer 15

1. AP propagates along the axon
2. AP opens voltage-gated channels at the presynaptic terminal
3. influx causes vesicle exocytosis
4. NT binds to receptors on the post synaptic membrane to activate them for post-synaptic activity
5. NT dissociates from the receptor and is metabolised by enzymes in the synaptic cleft or is recycled by transporter proteins

Question 16

Give some common features of neurones

Answer 16

Soma - contains nucleus and ribosomes
Axons - originates from the soma at the axon hillock and branch off into collaterals (myelinated)
Dendrites - highly branched endnote covered in myelin, receiving signals from other cells

Question 17

What are the 4 major physiological ions for RMP

Answer 17

potassium, sodium, chloride, calcium

Question 18

How is resting membrane potential generated in neurones

Answer 18

Cell membranes are impermeable to some ions so transportation is regulated by channels and pumps which cause uneven ion distribution. Differences in concentration produces the potential difference

Question 19

Describe the process of action potential generation in neurones

Answer 19

1. sodium channels open to induce sodium influx
2. depolarisation
3. potassium channels open at a slower rate
4. depolarisation of the cell
5. sodium potassium ATPase restores the gradient

Question 20

What is the function of myelin

Answer 20

Prevents AP propagation

Question 21

What is the function of nodes of Ranvier

Answer 21

Provides small gaps that the AP can jump across for faster transmission

Question 22

What is the function of skeletal muscle

Answer 22

Produces movement relative to the external environment

Question 23

What do antagonist muscle pairs consist of

Answer 23

Flexor (bicep)

Extensor (tricep)

Question 24

What is isotonic contraction ands what are the two types

Answer 24

Muscle changes length while tension remains the same
concentric - shortening
eccentric - lengthening
muscle tension > force exerted by load

Question 25

What is isometric contraction

Answer 25

tension develops but muscle does not change in length e.g. carrying a bag
muscle tension = force exerted by load
myosin heads reattach to the same point on the actin chain

Question 26

Describe the ultrastructure of skeletal muscle myofibres

Answer 26

Consists of myofibres (bundles)
large and cyclindrical
multinucleated
packed with myofibrils
sarcoplasmic reticulum - calcium stores 
T-tubules

Question 27

Describe the structure of a sarcomere

Answer 27

Z-line - Lateral boundaries
Actin - Polymeric thin filament composed of two twisted 𝛼-helices - displays polarity
Myosin - Thick filaments with globular heads that interact with actin
Titin - Very large springy filaments anchoring myosin to the Z-line
Nebulin - Large filaments associated with actin
Tropomyosin - Elongated protein bound to actin
CapZ & Tropomodulin - associated with +ve & –ve ends of actin, respectively

Question 28

Explain sliding filament theory

Answer 28

1. Ca2+ release -> movement of troponin from tropomyosin
2. Exposure of the myosin binding site on the actin chain
3. Charged myosin heads bind to the exposed sites
4. Binding + ADP discharge causes the myosin head to pivot (power stroke), pulling the actin filament towards the centre of the sarcomere
5. ATP binding releases myosin head from the actin chain
   ATP hydrolysis provides energy to recharge the myosin head

Question 29

Explain the process of excitation in skeletal muscle

Answer 29

1. Action potential propagates along the myofibre membrane (sarcolemma) 7 T-tubules
2. Depolarisation activates dihydropyridine receptors (DHPR)
3. Conformational change in DHPR
4. Transmission to ryanodine receptors (RyR) on sarcoplasmic reticulum
5. Opening of RyR & release of Ca2+ from intracellular stores
6. Depolarisation -> increase in intracellular Ca2+

Question 30

What are the pacemaker cells of the heart

Answer 30

SA node : small empty spindle shaped cells that are spontaneously active
AV node: spindle shaped network of cells at the base of the right atrium

Question 31

What are the conducting fibres of the heart

Answer 31

Bundle of His: fast conducting cells adjoining AV node and Purkinje fibres
Purkinje fibres: large cells for rapid conduction

Question 32

What are intercalated disks in cardiac muscle

Answer 32

specialised regions connecting individual cardiomyocytes

contains numerous gap junctions for APs to spread

Question 33

Describe excitation contraction coupling in cardiomyocytes

Answer 33

Same as skeletal muscle

depolarisation opens voltage-gated calcium channels

Question 34

What effects does calcium have in cardiac muscle

Answer 34

Ca2+ induced Ca2+ release by binding to RyR on SR
Initiate contraction binding to troponin
Further depolarisation

Question 35

Describe the structure of smooth muscle

Answer 35

in walls of hollow organs e.g. blood vessels and the GI tract
doesn’t have the regular arrangement of actin and myosin

Question 36

Explain the process of excitation contraction coupling in smooth muscle

Answer 36

1. Depolarisation activates voltage gated Ca2+ channels
2. Ca2+-CaM complex activates myosin light chain kinase
3. MLCK phosphorylates myosin light chains
4. Cross -bridges form with actin filaments -> contraction

Question 37

Why do cells communicate

Answer 37

process information, self preservation, voluntary movement, homeostasis

Question 38

Describe endocrine signalling and give an example

Answer 38

hormone travels via blood vessels to act on a distant target cell
Glucagon is secreted from the pancreas travels in the blood stimulates glycogenolysis and gluconeogenesis in the liver
others: insulin acting on liver, muscle cells and adipose tissues
adrenaline from glands acting on the trachea

Question 39

Describe paracrine signalling and give an example

Answer 39

Hormone acts on an adjacent cell
insulin released by beta cells inhibits glucagon secretion in adjacent alpha cells (+endocrine)
others: NO in endothelial cells in blood vessels
Osteoclast activating factor produced by adjacent osteoblasts

Question 40

Describe aubocrine signalling and give an example

Answer 40

Signalling molecule acts on the same cell
Activated TCR initiates a cascade of reactions in the cell, expressing interleukin 2 receptor. Secretion of IL-2 also binds to IL-2 receptor on the same cell
other: acetycholine
growth factors e.g. TGFB form tumour cells

Question 41

Describe signalling by membrane attached proteins and give an example

Answer 41

plasma membrane proteins on adjacent cells interacting
APCs presenting parts of the pathogen through MHC I
circulating T cells engage with MHC molecules through TCR
others: HIV GP120 glycoprotein
bacterial cell wall components

Question 42

Describe ionotropic receptors

Answer 42

Ligand binding opens an ion permeable pore leading to a signal transduction event

1. ligand binds to receptor
2. change in conformation of channel
3. pore opens
4. movement of ions according to gradient

Question 43

Give an example of ionotropic receptor action

Answer 43

nicotinic acetylcholine
Acetylcholine causing muscle contraction in skeletal muscle

GABAa (gamma amino butyric acid) causes a decreases in neuronal excitability in neurones

Question 44

Describe G-protein coupled receptors

Answer 44

Ligand binds to activate an intracellular G-protein
1. 7-TM receptor + heterotrimeric G-protein are inactive
2. Ligand binds changing conformation of the receptor
3. G-protein binds to the receptor
4. GDP exchanged for GTP
5. G-protein dissociates into 2 active units (alpha & gamma+beta)
6. units bind
7. GTPase dephosphorylates GTP to GDP
8. alpha subunit dissociates and becomes active
Receptor is active as long as the ligand is bound

Question 45

What are the 3 types of G-protein coupled receptors and what are their functions (+examples)

Answer 45

Gs - stimulates adenyl cyclase
ATP -> cyclic AMP -> Activated protein kinase A
e.g. beta adrenergic receptor to increase heart rate

Gi - inhibits adenylyl cyclase
reduces PKA levels
e.g. Muscarinic receptor to decrease heart rate

Gq - stimulates phospholipase C
PIP2 -> IP3 + DAG -> calcium release + PKA activation
e.g. angiotensin receptor to vasoconstrict

Question 46

Describe enzyme-linked receptors

Answer 46

Ligand binds to cause clustering of receptors

1. ligand binds
2. receptors cluster to activate enzymes
3. enzymes phosphorylate the receptor
4. signal proteins bind to cytoplasmic domain
5. recruit other signal proteins to generate the signal

Question 47

Give an example of enzyme-linked receptors

Answer 47

insulin receptor (CD220)
insulin causes glucose uptake

ErbB
Epidermal growth factor causing cell growth and proliferation

Guanylyl-cyclase
Atrial natriuretic peptide causes vasodilation to decrease blood pressure

Ser/Thr-kinase
Transforming growth factor beta causes apoptosis

Question 48

Describe type 1 signal transduction

Answer 48

cytoplasmic
association with chaperone molecules (heat shock proteins)
1. hormone binds to receptor
2. HSP dissociates
3. 2 hormone-bound receptors -> homodimer
4. translocates -> nucleus + binds to DNA

Question 49

Describe type 2 signal transduction

Answer 49

nuclear

1. hormone ligand binds
2. transcriptional regulation

Question 50

Give an example of signal transduction

Answer 50

glucocorticoid
cortisol/corticosterone causes a decrease in immune response and an increase in gluconeogenesis

Thyroid hormone
T4 and T3 cause growth and development

Question 51

Give 3 common skin diseases

Answer 51

acne
eczema
psoriasis

Question 52

Give some functions of skin

Answer 52

Protection against injury and pathogenic organisms
Waterproofing and fluid conservation
Thermoregulation (~36.8) through blood flow (sympathetic) and sweating
Protection against radiation, absorption of ultra violet radiation and vitamin D production
Surface for grip
Sensory organ
Cosmetic

Question 53

What are the 4 layers of the epidermis

Answer 53

Keratinocytes
Stratum Corneum
Stratum granulosum
Stratum spinosum
Stratum basale

Question 54

Outline the very basic structure of the skin

Answer 54

Epidermis
Basement membrane
Dermis

Question 55

Give some other components of the skin

Answer 55

desmosome
sweat glands
hair/ hair follicle
sebaceous glands

Question 56

Describe the Stratum corneum

Answer 56

corneocytes (flat with no nuclei)
Protective
Filagrin gene mutation leads to eczema

Question 57

Describe Stratum Spinosum

Answer 57

prickle/spinous cells that produce keratin

Desmosomes

Question 58

Describe Stratum Basale

Answer 58

Basal cells that connect to eh basement membrane

Keratinocytes found here

Question 59

Give some other components of the epidermis

Answer 59

Melanocytes (production of melanin)
Langerhans cells (antigen presenting)
Merkel cels (sensation)

Question 60

Describe the basement membrane in the skin

Answer 60

Highly specialised region where epidermis meets dermis
via hemidesmosomes, anchoring plaques and proteins
Blisters are common e.g. epidermolysis bullosa

Question 61

Describe the structure of the basement membrane in skin

Answer 61

hemidesmosomes
tonofilaments
demo-epidermal junctions
anchoring fibrils

Question 62

Describe the dermis

Answer 62

supportive connective tissues - collagen, elastin, GAG
Thickness varies between 0.1mm and 3mm
contains fibroblasts that synthesises collagen, elastin and GAG
Dendritic cells found here

Question 63

Describe the subcutaneous layer

Answer 63

Connective tissue and fat

Question 64

Describe the pilo-sebaceous unit of the skin

Answer 64

Follicle
Hair shaft
Sebaceous gland
Pilo-erecti muscle

Question 65

What are the two types of sweat glands found in skin

Answer 65

Apocrine - only located in the axillary and groins that produce discus sweat - subject to bacteria and therefore produce odour
Eccrine

Question 66

What are the components of the dermo-epidermal junction

Answer 66

Lamina lucida
Lamina densa
Anchoring fibrils
Hemidesmosomes 
Anchoring filaments

Question 67

Explain the role of melanocytes and their development

Answer 67

Dendritic cells in Stratum Basale
Produces melanin pigment in the melanosome, which is then packed into granules that are transferred to adjacent keratinocytes via phagocytosis
Granules form a protective cap around the nuclei to protect DNA from UV (which stimulates melanin production)
Variation in pigmentation is from no. and size of melanosomes

Question 68

What are the 3 types of hair

Answer 68

Lanugo
Vellus
Terminal

Question 69

Describe Lanugo hair

Answer 69

Fine whispy and long hair
Found in the foetus at 20 weeks and in anorexic people
Shed before birth

Question 70

Describe vellus hair

Answer 70

Short, fine, light hairs that cover the body

Question 71

Describe terminal hair

Answer 71

Long, thick, dark hair
Scalp, eyebrows, eyelashes, pubic, axillary
Starts at vellus and androgens make it terminal

Question 72

Describe the hair follicle

Answer 72

Made up of pilo-sebaceous units
Hair follicle
Hair shaft
Erector pili muscle
Sebaceous gland
Hair bulb- blood from the dermal papilla

Question 73

What are the 3 stages in hair growth

Answer 73

anagen
catagen
telogen

Question 74

Describe anagen in hair growth

Answer 74

growth phase (85% cells)
Energy intensive + highly vascularised
Most metabolically active
Rate depends on body site

Question 75

Describe catagen in hair growth

Answer 75

Cell devision slows and stops
End of shaft keratinises to form a club shape
Dermal papillae and club moves to the base of muscle insertion

Question 76

Describe telogen in hair growth

Answer 76

Hair is shed actively
Next anagen phase begins
Club hair takes 4-6 weeks

Question 77

What is synchronicity in hair growth

Answer 77

when a baby is born, all the hair growth cycles are in synchronicity

Question 78

How does age affect hair growth

Answer 78

Telogen effluvium - the thinning of hair due to early entry to telogen
Due to emotional and physiological stress or hyperthyroidism, sepsis and anaemia

Question 79

How do sex hormones affect hair growth

Answer 79

testosterone on the follicles
There is a surge during puberty which grows terminal hair
Pubic and axillary, then beard and chest, then nose and ear hair
Androgen sensitivity - balding pattern

Question 80

What are nails made of

Answer 80

Hard hair keratin

Question 81

Describe the growth of nails

Answer 81

Nails grow from the Germinal matrix

Question 82

Describe the structure of the nail

Answer 82

Distal end is the lunula/germinal matrix (critical to growth) - white moon
eponychium - skin cover
hyponychium
onychodermal band - overhang of nail

Question 83

Describe the growth of nails

Answer 83

Fingernails - 3mm a month
Toenails - 1mm a month
Due to adhesion and nail folds, the nail grows out and not up
Nail surface is produced by the proximal nailbed