:))

Question 1

where is type 4 collagen found?

Answer 1

* basal membrane *

Question 2

where do u find reticular connective tissue?

role?

Answer 2

• found at boundary of connective tissue and epithelium
• supporting stroma for highly cellular organs (like liver).
  function: wound healing and scar tissue.

Question 3

what do u stain to see elastic fibres

Answer 3

orcein

Question 4

what is ECM made of?

Answer 4

1. proteoglycans
2. collagens
3. noncollagenous glycoproteins (fibronectin and laminin)

Question 5

what is special about myofibroblast - what do they do?

Answer 5

myofibroblasts:

(- appear similar to fibriblasts)

• express alpha smooth muscle actin.
• differ from smooth muscle cells bc lack external basal lamina

Question 6

where are mast cells not found? where found tho

Answer 6

• NOT found in: brain and spinal cord ( remember this!!)
• found in: CT of skin and mucous (and other places too)

Question 7

what is the name of the thick layer of dense irregular connective tissue in the skin?
what is the layer find above this?

Answer 7

• *above:** papillary
• *thick =** reticular layer

Question 8

where are viral replication sites for viruses?

which type go where?

Answer 8

• *cytoplasm**: most RNA viruses
• *nucleus**: most DNA viruses

(some do both e.g. retroviruses)

Question 9

what are the subunits of viral capsids called?

Answer 9

capsomere: usually associate with, or are found close to, the virion nucleic acid.

Question 10

what are normal 4 strucutres of viruses?

name a virus that is an exceptions to the normal 4 structural categories of viruses?

Answer 10

exception: pox virus

Question 11

what is the baltimore classification system?

Answer 11

dsDNA viruses
ssDNA viruses
dsRNA viruses
(+)ssRNA viruses
(-)ssRNA viruses
ssRNA-RT viruses
dsDNA-RT viruses

Question 12

what type of virus (from baltimore classification) is:

• coronavirus
• influenza
• HIV?

Answer 12

• coronavirus: (+)ssRNA viruses
• influenza:(-)ssRNA viruses
• HIV: ssRNA-RT viruses

Question 13

explain how oral and oespophageal cancers are caused by excess alchohol intake

Answer 13

• *ethanol:**
• reaction: ethanol –> acetaldeyde
• acetaldeyde reacts with deoxyguanosine = weak mutagen. further reaction -> stronger mutagen (DNA adduct)
• *UV**
• p53 implicated
• formation of cylobutane pyrmindine dimers (CPD) covalent bonds form between 2 adjacent pyrimidines in same DNA strand. VERY STRONG BOND

Question 14

what is the mutation that occurs in ras gene to make it mutagenic?

Answer 14

• single nucleotide exchange GGC TO GTC in bladder cancers (glycine -> valine)

Question 15

which cancers does XPA gene increase chance of?

Answer 15

a) Non-melanoma (basal cell and squamous cell) skin cancer at UV exposed sites

• • patients with XPA mutation have 10, 000 x increased risk*
• • median age onset 9 years (c.f. 60 in general pop)*

b) cutaneous melanoma (melanocytes)

• • patients with XPA mutation have 2000x increased risk*
• • median age: 22 years (c.f. 30 years)*

Question 16

2. what are the three main mechanism of gene alterations that activate oncogenes?

Answer 16

- point mutations: single base change in DNA (e.g. Ras oncogene)

- chromsomal rearrangements: translocation of chr activates oncogene by using regulatory elements from a highly transcribed gene to drive expression of oncogene

- gene amplification (e.g HER2)

Question 17

where is c-myc normally encoded?

where is IgH normally encoded?

explain cancer that occurs when the above translocate

Answer 17

• c-myc: found on chr 8
• on chromsome 14, there is a gene that codes of IgH - has a very strong promoter
• translocation of region of chr 8 and 14: myc gets translocated near to promoter of IgH
• results in strong promoter driving the expression of myc: Burkitt lymphoma

Question 18

what is a cause of lymphoma?

Answer 18

• strong promoter of IgH on chromosome 14 translocates to chromsome 18
• switches ON bcl-2 gene (anti-apoptotic protein) in active B-lymphocytes (is normally switched off)
• cells that harbour mutations do not go into apoptosis
• causes lymphoma

Question 19

describe how DNA methylation can lead to tumour suppression (epigenetics) in promoter region

Answer 19

• methylation moves from lysine 4 of the histone 3 (H3) (normal function) to lysine 9 of H3
• leads to transcriptional repression & loss of tumour suppressor gene expression

Question 20

what type of gene is hudsons two hit hypothesis about?

Answer 20

tumour supressor genes

Question 21

how does DNA damage occur by formation of DNA adducts in lung cancer?

how does DNA damage occur by UV radation ? and where

Answer 21

• *smoking**
• (benzopryene (BP) from smoke is oxidised (x2))- results in BPDE (ultimate carcinogen)
• BPDE forms adduct with guanosine residues in lung epithelial cells
• occurs often in tumour suppressor genes, such as p53
• *UV**:
• damage in basal cells of melansomes (particularly keratinocytes)
• p53 implicated
• formation of cylobutane pyrmindine dimers (CPD) covalent bonds form between 2 adjacent pyrimidines in same DNA strand. VERY STRONG BOND

Question 22

what does HPV cause?

Answer 22

HPV: cervical cancer

Question 23

how do cancer cells become insensitive to anti growth signals?

Answer 23

Insensitivity to anti-growth signals:

There are genes that normally express growth suppressing signals e.g. TP53 and RB involved in the cell cycle, but can be mutated in cancer

Therefore there are no longer gatekeeping mechanisms to keep cell cycle progression in check.

Question 24

what do cancer cells express to maintain telomere length?

Answer 24

So, in normal cells, when the telomeres are short enough, it looses its protective ability and the cell is triggered into apoptosis.

In cancer cells, telomerase (not normally expressed in healthy cells) is expressed which counters the erosion to telomeres and therefore removes a barrier to proliferation and the cell will achieve immortality.

Question 25

which gene encodes for sustained angiogenesis in cancer cells?

Answer 25

Controlled by a signalling molecule - VEGF.

This function is normally “turned off” unless needed (e.g. wound healing) but in cancer cells is is permanently “switched on”.

Allows more nutrients to be delivered to tumour for growth.

Question 26

h-ras (and mutated k-ras) is an example of what type of protein?

how work?

Answer 26

SIGNAL-TRANSDUCTION PROTEINS:

RAS if active, it SENDS GROWTH PROMOTING SIGNALS TO THE NUCLEUS

KRAS is continuously active

↓

Signals for cell division

↓

Continuous proliferation

Question 27

ovexpression in the following causes what cancers:

VEGF
PDGF
TGFα

Answer 27

VEGF = BPH (benign prostate hyerplasia)

PDGF = Glioblastoma

TGFα = Oesophageal cancer

Question 28

what does pRB do in normal cell? when causes cancer?

Answer 28

PREVENTS PROGRESSION FROM G1 TO S BY INHIBITION OF S-PHASE GENES EXPRESSION

cause cancer when:

Phosphorylated Rb -> E2F is released -> Transcription and gene expression ->Progression from G1 to S phase

Question 29

which immunuglobulin is made first in an immune response? which one is it followed by?

Answer 29

IgM: primary immune response

Question 30

what are the two hypothesis for the generation of cancer stems cells?

Answer 30

1. cancer stem cell model
2. clonal evo model

Question 31

epithelial tumours are derived from which germ layers?

connective tissue tumours are derived from which germ layers?

bone tumours are derived from which germ layers?

nervous tumours are derived from which germ layers?

Answer 31

• epithelial tumours dervied from: ectoderm, endoderm and mesoderm
• connective tissue tumours dervied from: mesoderm
• bone tumours dervied from: mesoderm
• nervous tissue tumours dervied from: ectoderm

Question 32

where do u find stratified squamous cells?

where do u find simple cuboidal and simple columnar ?

important!!

Answer 32

stratified squamous: covering and lining epithelia - lining of skin / lining of internal organs / forms lining of ducts and body cavities (nasal cavity, larynx, lung, cervix and skin)

simple cuboidal / columnar: glandular epithelia - thyroid, adrenal and sweat glands. glands in breast and prostate (lung, colon, breast, pancreas, stomach, prostate))

Question 33

how do u know if a tumour is benign?

Answer 33

-oma !

Question 34

what are the charcateristics of cancer cells? (4)

Answer 34

• immortal
• high cell division
• ischemic necrosis in middle of tumour -> centre of tumour lacks food / O2 so cells die
• shedding or loss of tumour cells
• Grade 1 -> Grade 3 cancer: cells become less differentiated / undifferentiated

Question 35

what are keratin pearls and what do they show?

Answer 35

• when invading tumour cells retain ability to synthesis keratin - keratin becomes trapped inside the tumour: keratin pearls
• demonstrates still fairly differentiated

Question 36

how do you grade and stage tumours?

Answer 36

Grading depends on:

1. degree of anaplasia (degree of differentiation) -> more undifferentated = lower grade
2. rate of growth

Stage depends on:

1. size of tumour
2. spread / extent of tumour

TNM: - Tumour (size), Nodes: has it spread to lymph nodes? M: has it mestasistsed

Question 37

what are paraneoplastic syndromes?

Answer 37

• paraneoplastic syndromes: clinical syndromes not caused by direct invasion or metastasis of tumour which accompany malignant disease. non-metastatic manifestation of malignant disease
• associated with malignancies in: lung, breast, gynaecologica and haemotoligcal tumours
• arise from tumour secretion of hormones, peptides, cytokines -> interfere with normal metabolic pathways of hormones peptides

Question 38

which organs are the primary lymphoid organs?

which are secondary lymphoid organs?

Answer 38

thymus and bone marrow - where cells are made

spleen, lymph nodes and lymphatic vessels

Question 39

how does a bacterial superinfection occur?

Answer 39

viral resp tract infections followed by bacterial superinfection:

• mucociliary escalator (moves mucous out of lungs to be expelled by coughing) damaged
• viral infection OR inflammation can damaeg mucociliary escalator
• mucous not expelled
• followed by bacterial superinfection

Question 40

how u diagnose resp. tract infections? (2)

what is a ct value / high or low ct value?

Answer 40

PCR - using a nasal pharyngeal swab:

• nucleic acids from virus is picked by virus panel -> recognise the viruses
• (can also check for bacterial panel to d/c if pneumonia is bacterial)
• *- ct value: no. of rounds of replication required to ID virus on swab**
• high ct value: need lots of rounds of replication (low virus no.)
• *- low ct value:** need few rounds to detect to virus

Question 41

Q

what is influenza virus structure like?

what is influenza virus serology like?

Answer 41

• *- Orthomyxovirus (family)**
• enveloped
• surface spikes: Hemagglutinin protein (HA) (16 types), Neuraminidae protein (NA) (9 types)
• SS(-)RNA
• 8 segmented genes
• serology:
• A = humans, animals and birds
• B = humans only (more chill)
• C = humans only (more more chill - mild resp. tract infections)

Question 42

Q

describe the genome of influenza / how this influences transmission?
what is transmission cycle like?

A

Answer 42

genome: segmented - many different parts are expressed on individual nucleic acid pieces: if two viruses infecting the same cell -> pieces swap around (reassortment) and get new varients

• *point mutations**
• single point mutations only genome - change antigen
• most meaningful mutations occur in HA1 protein
• *antigenic shifts:**
• mixing of genomes: genetic reassortment between circulating human and animal strains. creates novel H/N combinations
• accounts for emergence of new strains of virus
• *- only in type A**

Question 43

what are Vaso vasorum?

Answer 43

(blood vessels of blood vessels: blood carried from inner part of BV to outer par) and autonomics

Question 44

when does thoracic aorta start? become abdominal aorta?

Answer 44

starts: T4
ends: T12 - becomes abdominal aorta

Question 45

what does the short / lesser saphenous vein flow into/

Answer 45

popliteal vein

Question 46

how does excess fluid get back into the veinous system?

Answer 46

lymphatic system drains back into the right and left venous angle: junction where subclavian vein and internal jugular vein meet

Question 47

what stimulates cutaneous vasoconstriction when its cold?

Answer 47

sympathetic NS: noradrenaline on alpha adrenoreceptors

Question 48

what is an arteriovenous anastomoses?

Answer 48

BV that provide a route for blood to bypass from the arterioles directly to venules, bypassing capillaries

• found in hands, feet, nose, ears and lip skins

Question 49

what happens at the stem cells in stratum basale?

Answer 49

stratum germitativum: new keritonocytes form from the stem cells found in stratum basale by mitotic division

Question 50

what’s found in the keratinocytes of stratum granulosum?

Answer 50

• k with keratohyalin granules: cystine and histidine protein granules, which are precurosrs of fillagrin, which aggregates the keratin filaments

Question 51

what are the langerhan cells? derived from? role?

how do u stain them?

Answer 51

• derived from: bone marrow
• function: interact with keratinocytes through E-cadherins. grab antigens when they see one -> then travel to lymph node to present the antigen and then t-lympocyte activate
• stain: protein marker S100

Question 52

basal cells of epidermis cells are attached to what?

what do adherens and desmosomes, tight junctions and gap junctions do in epidermis basal lamina?

Answer 52

• basal cells adhere to ECM rich basement membrane: consists of Laminin 332, Collagen IV and Collagen VII)
• adherens and desmosomes: attach cells extra- and intracellularly, mech support and integrity of epi
• tight junctions: seal up intercellular space - prevent bacteria passing through
• gap junctions: communication, nutrients

Question 53

what is cell structure like of eccrine sweat glands?

Answer 53

stratified cuboidal

Question 54

what do the different skin receptors detect?

Answer 54

• *1. meissner’s corpsucles:** respond to fine touch and pressure & low vibration frequency. encapsulated nerve endings (axon surroundered by schwann cells)
• *2. pacinian corpuscles:** look like onions. myelinated nerve ending in the centre. deep in dermis. sensitive to vibration and pressure
• *3. ruffini endings:** deeper in base of epidermis - detect skin stretch, joint activity and warmth. finger position and movemen

Question 55

what is the change that occurs in Hb S?

Answer 55

Single base mutation of Adenine to Thymine. Produces a substitution of valine for glutamic acid at the sixth codon of the beta-globin chain. Hb gene found on chromosome 11

Question 56

which is the most common deletetion in CF?

Answer 56

most common mutation: phenylalanine 508 deletion (deletion of CTT: frameshift mutation = less stable protein)

Question 57

what are someo of the different mechanisms of spontaneous mutations?

Answer 57

1. tautomeric shift (base substitution)

2. depurination

3. deamination

Question 58

what is depurination mutation?
what is a deamination mutation?

what are most deamination and depurination errors corrected by?

Answer 58

depurination:
- loss of a purine base (A or G)
- leads to deletion mutation
(can occur in double DNA helix)

• *deamination:**
• removal of the amino (-NH3) group through hydrolysis water
• leads to substitution reaction

corrected by: polymerase enzymes

Question 59

how does UV radiation cause indirect mutations?
what is the effect of DNA damage by UV radiation to melanocytes?

Answer 59

• *indirect:** ionizing radiation creates free radicals that damage DNA by reacting with it
• *melanocytess:** pyrimindine dimers -> formed when cyclobutane rings occur between adjacent, same strand pyrimidines in DNA

Question 60

how do H. pylori and HPV cause cancer?

Answer 60

Helicobacter pylori: causes stomach cancer. 50% of pop. is infected. causes mutation rate of stomach cells to increase by 2-8% higher spontanous rate. also get epigenetic changes. DNA repair loss

Human papilloma virus: common sexually transmitted virus. viral DNA incorporated into host. produces protein called E6. E6 binds to p53 (tumour supressor) and directs p53 for degradation. disables normal DNA damage repair processes