Cellular adaptions

Question 1

cell population controlled by

Answer 1

• Rate of cell proliferation
• Physiological and pathological
• Rate of cell differentiation
• Rate of cell death by apoptosis

Question 2

Increased numbers=

Decreased=

Answer 2

Increased numbers= proliferation

Decreased= cell death

Question 3

Control of cell proliferation by

Answer 3

• proto-oncogenes and tumour suppressor genes
• chemical mediators from microenvironemnt

Question 4

signalling moelcules modulate gene expression by binding to receptors on the :

Answer 4

• cell membrane
• cytoplasm
• nucleus

Question 5

cell cycle overview

Answer 5

G1

G1 checkpoint

S phase

G2

G2 checkpoint (restriction point)

M and cytokinesis

Question 6

G1

Answer 6

cellular contents excluding the chromosome are duplicated

Question 7

G1 checkpoint

Answer 7

• Is the cell big enough
• Is environment favourable
• Is DNA damaged?

Question 8

S phase

Answer 8

each of the 46 chromosomes are duplicated by the cell

Question 9

G2

Answer 9

cell doublechecks the duplicated chromosomes for error- makes repairs

Question 10

G2 checkpoint (restriction point)

Answer 10

• Is all DNA replicated?
• Is the cell big enough?
• Enter M

Question 11

M and cytokinesis- mitosis

Answer 11

• Division of cell to produce 2 identical sister cells
• Prophase
• Metaphase
• Anaphase
• Telophase and cytokinesis

Question 12

if there are defects in checkpoints

Answer 12

uncontrolled division

Question 13

what regulate checkpoints

Answer 13

cyclins

Question 14

the restriction (R) point is governed by

Answer 14

P53

Question 15

the majority of cells that pass the R point will

Answer 15

complete cell cycle- point of no return

Question 16

the R point is the

Answer 16

most commonly altered checkpoint in cancer cells

Question 17

checkpoint activation at the R point

Answer 17

delays cell cyel and triggers DNA repair mechanisms or apoptosis via P53

Question 18

P53- the guardian of the genome - activators

Answer 18

• DNA damage
• Oncogene expression
• Hypoxia
• Oxidative stress
• Nutrient deprivation

Question 19

what occurs as a reuslt of P53

Answer 19

• Senescence
• Cell cycle arrest
• Apoptosis
• DNA repair

Question 20

all results of P53 activation result in

Answer 20

tumour supression

Question 21

in 70% of cancers

Answer 21

P53 mutation

Question 22

P53 pathway

Answer 22

1. DNA is damaged
2. Increase in activated P53 either induces
   
   1. Apoptosis
   2. Or Increase in p21
      
      1. Prevent phosphorylation of cyclins
      2. Cell cycle arrest
      3. Allow DNA repair

Question 23

cyclins and CDK

Answer 23

• Cyclin dependent kinases (CDKs) become activated when cyclins bind

Question 24

what do CDKs do

Answer 24

• phosphorylate proteins which have downstream effects such as increased transcription of proteins which increase cellular proliferation

Question 25

For each part of the cell cycle to commence

Answer 25

specific cyclins must binds to CDKS

Question 26

cyclin inhibitors e.g. retinablastoma (RB) protein and P21

Answer 26

e.g. retinoblastoma (RB) protein

1. RB is bound to TF (e.g. E2F-DP1) preventing it from entering the nucleus and transcribing
2. When cyclin binds to CDK the CDK phosphorylates the RB protein
3. This releases the TF so it can enter the nucleus and transcribe proteins that will cause cellular division (protooncogenes)

Question 27

How can cells adapt

Answer 27

• hyperplasia
• hypertrophy
• metaplasia
• aplasia
• hypoplasia
• involution
• reconsturction
• atresia
• dysplasia

Question 28

hyperplasia simple

Answer 28

cells increase in number above normal

Question 29

hypertrophy simple

Answer 29

icnrease in cell size

Question 30

atrophy

Answer 30

cells become smaller

Question 31

metaplasia

Answer 31

cells are replaced by cells of different type

Question 33

hyperplasia occurs in

Answer 33

• Labile (resting/slow turnover) tissues

Question 34

hyperplasia is caused by

Answer 34

• increased functional demand or hormonal stimulation (e.g. regeneration of the liver)
• Remains under physiological control and is reversible
• Can occur secondary to pathological cause but the proliferation itself is a normal response

Question 35

risk of hyperplasia

Answer 35

exposes cell to risk of mutations and neoplasia

Question 37

physiological hyperplasia

Answer 37

• Proliferative endometrium under influence of oestrogen
• Bone marrow produces erythrocytes in response to hypoxia

Question 38

pathological hyperplasia

Answer 38

• Eczema
• Thyroid goitre iodine deficiency

Question 39

hypertrophy occurs in

Answer 39

• Labile, stable but especially permanent tissues

Question 40

when does hypertrophy occur

Answer 40

• Increased functional demand or hormonal stimulation
• Usually occurs alongside hyperplasia

Question 41

why do cells need to grow

Answer 41

• Cells contain more structural components e.g. cytoplasm- workload is shared by a greater mass of cellular components

Question 42

physiological hypertrophy

Answer 42

• Skeletal muscle e.g. building muscle in the gym
• Pregnant uterus (hypertrophy + hyperplasia)

Question 43

pathological hypertrophy e.g.

Answer 43

• Hypertrophy of the heart
  
  • Athletes and cardiac hypertrophy- no. of capillaries will increase- but only to a certain extent- can cause ischaemia–> heart arrhythmias
• Obstruction of the urethra increases amount of urine needed to be held in the bladder at any time

Question 44

compensatory hypertrophy example

Answer 44

if you remove one kidney the other will grow

Question 45

Atrophy

Answer 45

Shrinkage of a tissue or organ due to an acquired decrease in size and/ or normal number of cells

Question 46

why foes atrophy need to occur

Answer 46

• shrinkage in the size of the cell to a size at which survival is still possible
• Reduced structural components of the cell (e.g. cytoplasm)

Question 47

atrophy may result in

Answer 47

cell death

Question 48

atrophy is reversible or irreversible

Answer 48

reversible up to a certain point

Question 49

physiological atrophy

Answer 49

• E.g. ovarian atrophy in post menopausal women

Question 50

pathological atrophy

Answer 50

• Reduced functional demand= atrophy of disuse
• Loss of innervation= denervation atrophy
• Inadequate blood supply
• Inadequate nutrition
• Loss of endocrine stimulinBreast, reproductive organs
• Persistent injury
• Ageing= senile atrophy
• Pressure

Question 51

Reduced functional demand= atrophy of disuse

Answer 51

• Muscle atrophy after disuse
• Reversible with activity

Question 52

​Loss of innervation= denervation atrophy

Answer 52

Wasted hand muscles after median nerve damage

Question 53

Inadequate blood supply

Answer 53

Thinning of skin on legs with peripheral vascular disease

Question 54

Inadequate nutrition

Answer 54

Wasting of muscles with malnutrition

Question 55

Loss of endocrine stimulation

Answer 55

Breast, reproductive organs

Question 57

Persistent injury

Answer 57

Polymyositis (inflammation of muscle)

Question 58

Ageing= senile atrophy

Answer 58

Brain, heart

Question 59

Pressure

Answer 59

Tissues around an enlarging benign tumour (probs secondary to ischaemia)

Question 60

metaplasia (reversible change of one differentiated cell type to another) occurs in

Answer 60

labile cell types

Question 61

why does emtapalsia occur

Answer 61

• Altered stem cell differentiation
• Adaptive substitution of cells that are sensitive to stress by cell types better able to withstand the adverse environment
• Metaplastic cells are fully differentiated and the process is reversible

Question 62

metaplasia can lead to

Answer 62

dysplasia and cancer (no metapalsia across germ layers)

Question 63

example of metaplasia in lung tissue

Answer 63

Bronchial pseudostratified ciliated epithelium –> stratified squamous epithelium due to effect of cigarette smoke

Question 64

example of metaplasia in the oesphagus

Answer 64

Stratified squamous epithelium –> gastric glandular epithelium with persistent acid reflux (Barretts oesophagus)

Question 65

examples of how epitheilial metaplasia can lead to cancer

Answer 65

• Squamous metaplasia and lung squamous cell carcinoma
• Barrett’s epithelium and oesophageal adenocarcinoma
• Intestinal metaplasia of the stomach and gastric adenocarcinoma

Question 66

aplasia

Answer 66

• Complete failure of specific tissue or organ to develop

Question 67

aplasia is a

Answer 67

• Embryonical developmental disorder
  
  • E.g. thymic aplasia- infections and auto-immune problem
  • Aplasia of a kidney

Question 68

aplasia can also be used to describe

Answer 68

• an organ whose cells have ceased to proliferate e.g. aplasia of bone marrow in aplastic anaemia

Question 70

hypoplasia

Answer 70

• Underdevelopment or incomplete development of tissue or organ at embryonic stage- inadequate number of cells

Question 71

hypoplasia is in a spectrum with

Answer 71

aplais

Question 72

hypoplasia is not

Answer 72

the opposite of hyperplasia as it is a congenital condition

Question 73

involution

Answer 73

• Overlaps with atrophy
• Normal programmed shrinkage of an organ
• Uterus after childbirth, thymus in early life, pro and mesonephros

Question 74

atresia

Answer 74

• No orifice- failure for opening to form
• Congenital imperforation of an opening
• E.g.
  
  • Pulmonary valve
  • Anus
  • Vagina
  • Small bowel

Question 75

Dysplasia

Answer 75

• Abnormal maturation of cells within a tissue
• Potentially reversible
• Often pre-cancerous condition