6.6 - Immunology of the gut

Question 1

What is the surface area of the GI tract?

Answer 1

200m^2

Question 2

How big is the antigen load in GI tract and what does it consist of?

Answer 2

Massive antigen load consisting of:

• resident microbiota 10^14 bacteria
• dietary antigens
• exposure to pathogens

Question 3

What does microbiota mean?

Answer 3

A mixture of microorganisms that makes up a community within an anatomical niche

Question 4

What does microbiome mean?

Answer 4

Collective genomes of all microbiota in all the different anatomical niches

Question 5

Immunologically, what state is the GI tract in?

Answer 5

• state of ‘restrained activation’
• balances tolerance vs active immune response
• dual immunological role

Question 6

What does the GI tract need tolerance against? (2)

Answer 6

• food antigens
• commensal bacteria

Question 7

What does the GI tract need immunoreactivity against?

Answer 7

Pathogens

Question 8

What is the presence of bacterial microbiota in the gut essential for?

Answer 8

Immune homeostasis of the gut and development of a healthy immune system

Question 9

How do we study the effects of the microbiota on the immune system?

Answer 9

• gnotobiology
• colonise germ-free mice and give them a particular germ and compare them to normal house mice and look at the microbiota
• e.g. immunological defect in the development of the small intestine –> Peyer’s patches in germ-free mice will be fewer and less cellular than house mice
• e.g. immunological defect in expression of angiotensin 4 –> reduced Paneth cells

Question 10

How many gut bacteria vs cells do we have in the body?

Answer 10

10^14 gut bacteria and 10^13 cells in the body –> most densely populated ecosystem on earth

Question 11

What are the four major phyla of bacteria (4), and what else is also present in the body (2)?

Answer 11

• Bacteroidetes
• Firmicutes
• Actinobacteria
• Proteobacteria
• viruses
• fungi

Question 12

What do the gut microbiota provide for us? (4)

Answer 12

• provide traits we have not had to evolve on our own - genes in gut flora are 100x our own genome
• metabolise indigestible compounds
• defence against colonisation by opportunistic pathogens
• essential nutrients

Question 13

What host factors stimulate bacterial growth? (2)

Answer 13

• ingested nutrients
• secreted nutrients

Question 14

What host factors inhibit bacterial growth? (2)

Answer 14

• chemical digestive factors (bacterial lysis)
• peristalsis, contractions, defecation (bacterial elimination)

Question 15

How does bacterial content change as you go along the GI tract?

Answer 15

• stomach has the least due to HCl and pepsin + gastric lipase
• duodenum has more as it has bile acids
• by the time we get to the colon, there is a lot of bacteria because there are no host digestive factors

Question 16

What is dysbiosis?

Answer 16

Altered microbiota composition, lack of homeostatic immunological equilibrium

Question 17

Explain what the immunological equilibrium is.

Answer 17

• one side = symbionts - microbiota and humans live with each other but not with benefit or harm to either, they just live (regulation)
• middle = commensals - microorganisms that benefit from associating with host, but has no effect on host
• other side = pathobionts - symbionts that usually do not elicit inflammatory response, but under specific conditions can cause dysregulated inflammatory disease (inflammation)

Question 18

What happens when something goes wrong and pathobionts begin replicating?

Answer 18

Inflammation and disease

Question 19

What influences GI equilibrium/dysbiosis? (5)

Answer 19

• infection or inflammation
• diet
• xenobiotics
• hygiene
• genetics

Question 20

How can dysbiosis negatively affect the rest of the body? (5)

Answer 20

Through producing metabolites and toxins e.g:

• TMAO - increases cholesterol deposition in artery walls to cause atherosclerosis
• 4-EPS - associated with autism
• SCFAs (short chain fatty acids) - decreased numbers associated with IBD, increased numbers associated with neuropsychiatric disorders
• AHR ligands - associated with MS, rheumatoid arthritis, asthma
• bile acids

Question 21

What is the first line of defence the body has against pathogens?

Answer 21

Mucosal defence

Question 22

What are the three layers of mucosal defence?

Answer 22

• 1st - physical barriers
• 2nd - commensal bacteria - occupy an ecological niche and are an ecological barrier
• 3rd - immunological (lymphoid tissue) - MALT and GALT

Question 23

What are the two types of physical barriers (mucosal defence)?

Answer 23

• anatomical - epithelial barrier, peristalsis
• chemical - enzymes, acidic pH

Question 24

What is the epithelial barrier made up of?

Answer 24

• mucus layer - goblet cells
• epithelial monolayer with tight junctions
• Paneth cells (small intestine)

Question 25

What are Paneth cells and what do they do?

Answer 25

• bases of crypts of Lieberkuhn
• secrete antimicrobial peptides (defensins) and lysozyme

Question 26

What types of lymphoid tissue are there? (2)

Answer 26

• MALT (mucosa associated lymphoid tissue)
• GALT (gut associated lymphoid tissue)

Question 27

Where is MALT found?

Answer 27

• found in the submucosa below the epithelium, as a lymphoid mass containing lymphoid follicles
• follicles are surrounded by HEV (high endothelial venule) postcapillary venules, allowing easy passage of lymphocytes

Question 28

Which specific part of the body is packed full of MALT?

Answer 28

Oral cavity is rich in immunological tissue - pharyngeal, palatine and lingual tonsils especially

Question 29

How big is GALT?

Answer 29

Largest mass of lymphoid tissue in body

Question 30

What types of immune response is GALT responsible for?

Answer 30

Responsible for both adaptive and innate immune responses through generations of lymphoid cells and antibodies

Question 31

What are the two types of GALT?

Answer 31

• non-organised
• organised

Question 32

What are non-organised GALT? (2)

Answer 32

• intra-epithelial lymphocytes (sit between enterocytes) - make up 1/5 of intestinal epithelium e.g. T cells, NK cells
• lamina propria lymphocytes

Question 33

Describe the important cells in the small intestine villus.

Answer 33

• intestinal epithelial cells migrate up to tip of villus
• mucus-secreting goblet cells
• Paneth cells migrate to bottom of crypt (characterised by dense granules containing anti-microbial peptides)
• lamina propria makes up middle of villus and contains immune cells e.g. T cells, macrophages, DCs
• intra-epithelial lymphocytes are there between enterocytes

Question 34

What are organised GALT? (4)

Answer 34

• Peyer’s patches (small intestine)
• caecal patches (large intestine)
• isolated lymphoid follicles
• mesenteric lymph nodes (encapsulated)

Question 35

What do people mistake enlarged mesenteric lymph nodes as being?

Answer 35

Pathological even though they are just reactive, and are the largest lymph nodes you find in the body naturally

Question 36

Where are Peyer’s patches found?

Answer 36

Submucosa of small intestine - mainly in distal ileum

Question 37

What are Peyer’s patches?

Answer 37

Aggregated lymphoid follicles covered with follicle associated epithelium (FAE)

Question 38

What is follicle associated epithelium (FAE)?

Answer 38

Made up of specialised enterocytes with the role of transferring things (like bacteria) to Peyer’s patches

Question 39

What cells do FAE lack? (3)

Answer 39

• no goblet cells
• no secretory IgA
• lack microvilli

Question 40

What cells are Peyer’s patches made of?

Answer 40

Organised collection of naive T cells and B-cells

Question 41

What does the development of Peyer’s patches require?

Answer 41

Development requires exposure to bacterial microbiota

Question 42

How many Peyer’s patches do we have from last trimester of foetus to teens?

Answer 42

• 50 in last trimester
• 250 in teens

Question 43

How does antigen uptake occur in Peyer’s patches?

Answer 43

• via M (microfold) cells within FAE
• M cells express IgA receptors, facilitating transfer of IgA-bacteria complex into the Peyer’s patches

Question 44

What do M (microfold) cells have instead of microvilli?

Answer 44

Microfolds instead, through which bacteria get taken up

Question 45

What is an alternative route of bacteria uptake other than M (microfold) cells?

Answer 45

• antigen sampling: trans-epithelial dendritic cells
• trans-epithelial dendritic cells can open up tight junctions and squeeze out and send dendrites into lumen of GI tract and directly sample bacteria
• brings them back and transports them to mesenteric lymph nodes

Question 46

Describe the B cell adaptive response in the GI tract.

Answer 46

1. M cells take up pathogens
2. they are excreted into a pocket formed in inner surface of enterocyte
3. pocket contains APCs (DCs) that engulf antigen and presents them through MHC II
4. mature naïve B-cells express IgM in Peyer’s patches, and on antigen presentation class switches to IgA
5. T-cells and epithelial cells influence B-cell maturation via cytokine production
6. B cells further mature to become IgA secreting plasma cells and populate lamina propria (some APCs escape into lymph to go activate B and T cells in mesenteric lymph nodes, some of these activated cells return to gut tissue to produce antibodies)

Question 47

How do the IgA secreted by B cells get into the lumen?

Answer 47

• the IgA goes into a vesicle in the enterocyte
• enzymatic cleavage –> secretory IgA –> lumen
• up to 90% of gut B-cells secrete IgA

Question 48

What does secretory IgA (sIgA) do?

Answer 48

Binds luminal antigen to prevent its adhesion and consequent invasion

Question 49

Describe lymphocyte homing and circulation.

Answer 49

1. Peyer’s patch presentation and activation
2. lymphocytes travel to mesenteric lymph nodes where lymphocyte proliferation occurs
3. return to circulation through thoracic duct (main lymphatic vessel for return of lymph from GI tract to venous system)
4. it can now either go to peripheral immune system (skin, tonsils, BALT bronchus associated lymphoid tissue) OR return to intestinal mucosa via vessels in lamina propria

Homing cascade directs circulating naive T cells to Peyer’s patches

Question 50

How do lymphocytes move from blood vessels into lamina propria?

a4B7 integrin/MAdCAM-1 adhesion & gut homing

Answer 50

• HEV expresses MAdCAM1 (mucosal addressin cell adhesion molecule 1; tissue specific)
• lymphocytes express alpha4beta7 integrin and they adhere to MAdCAM1

1. lymphocytes roll along HEV wall (rolling)
2. rolling chemotactically activates T cell = alpha4beta7 integrin and MAdCAM1 interact (activation)
3. cell gets pulled into lamina propria (arrest)

Homing cascade directs circulating naive T cells to Peyer’s patches

Question 51

Why do enterocytes have such a short life span of 36 hours?

Answer 51

• enterocytes are first line of defence against GI pathogens and may be directly affected by toxic substances in diet
• effects of agents which interfere with cell function, metabolic rate etc will be diminished
• any lesions will be short-lived
• escalator-like transit of enterocytes (if interrupted through impaired production of new cells e.g. radiation –> severe intestinal dysfunction)

Question 52

What happens if escalator-like transit of enterocytes is interrupted through impaired production of new cells (e.g. radiation)?

Answer 52

Severe intestinal dysfunction

Question 53

What is the mechanism of infection of cholera?

Answer 53

• acute bacterial disease caused by Vibrio cholerae serogroups O1 and O139
• bacteria reaches small intestine –> contact with epithelium and releases cholera enterotoxin
• enterotoxin gets internalised by retrograde endocytosis
• this increases adenylate cyclase activity = increased cAMP
• increases active secretion of salts (Na+, K+, Cl-, HCO3-) via CFTR
• water follows and leads to diarrhoea

Question 54

How does cholera transmit?

Answer 54

Transmitted through faecal-oral route via contaminated water and food

Question 55

What are the main symptoms (2) and other symptoms (3) of cholera?

Answer 55

Main:

• severe dehydration
• watery diarrhoea

Other:

• vomiting
• nausea
• abdominal pain

Question 56

How do we diagnose cholera?

Answer 56

• bacterial culture from stool sample on selective agar is the gold standard
• rapid dipstick tests also available

Question 57

How do we treat cholera?

Answer 57

Oral-rehydration is the main management - up to 80% of cases can be successfully treated

Question 58

What vaccine is used for cholera?

Answer 58

• Dukoral
• oral
• inactivated

Question 59

What is the epidemiology of cholera?

Answer 59

• globally 1.3-4 million cases
• average 95k deaths a year

Question 60

What are some viral causes of infectious diarrhoea (gastroenteritis)? (2)

Answer 60

• rotavirus (children)
• norovirus (winter vomiting bug)

Question 61

Describe rotavirus (the virus).

Answer 61

• RNA virus, replicates in enterocytes
• 5 types A-E, type A most common in human infections

Question 62

What is the epidemiology of rotaviruses?

Answer 62

Most common cause of diarrhoea in infants and young children worldwide

Question 63

How do we treat rotaviruses?

Answer 63

• oral rehydration therapy
• still causes 200k deaths a year
• before vaccine, most people had infection by age 5 - repeated infections develop immunity

Question 64

What is the vaccination for rotavirus?

Answer 64

Live attenuated oral vaccine (Rotarix) against type A introduced in 2013 - very successful

Question 65

Describe norovirus (winter vomiting bug).

Answer 65

• RNA virus
• incubation period 24-48h

Question 66

How is norovirus transmitted?

Answer 66

• faecal-oral transmission
• individuals may shed infectious virus for up to 2 weeks
• outbreaks often occur in closed communities

Question 67

What is the main symptom of norovirus?

Answer 67

Acute gastroenteritis, recovery 1-3 days

Question 68

How do we diagnose norovirus?

Answer 68

Simple PCR

Question 69

What is the epidemiology of norovirus?

Answer 69

Estimated 685 million cases and 200k deaths a year

Question 70

What are some protozoal parasitic causes of infectious diarrhoea? (2)

Answer 70

• Giardia lamblia
• Entamoeba histolytica

Question 71

What are some bacterial causes of infectious diarrhoea (gastroenteritis)? (6)

Answer 71

• cholera (Vibrio cholerae subgroups O1&O139)
• Campylobacter jejuni
• Escherichia coli
• Salmonella
• Shigella
• Clostridium difficile

Question 72

How is Campylobacter (curved bacteria) transmitted?

Most common species: Campylobacter jejuni, Campylobacter coli

Answer 72

• undercooked meat (especially poultry), untreated water and unpasteurised milk
• low infective dose, a few bacteria (<500) can cause illness

Question 73

What is the treatment for Campylobacter?

Answer 73

• not usually required (excreted in few days)
• Azithromycin (macrolide) is standard antibiotic
• resistance to fluoroquinolones is problematic

Question 74

What is the epidemiology of Campylobacter?

Answer 74

• estimated 280k cases per year
• commonest cause of food poisoning in UK

Question 75

Describe Escherichia coli (E. coli)

Answer 75

• diverse group of gram -ve intestinal bacteria
• most harmless

Question 76

What are the six pathotypes of E. coli associated with diarrhoea?

Answer 76

• enterotoxic E. coli (ETEC)
• enteroinvasive E. coli (EIEC)
• enterohaemorrhagic or Shiga toxin-producing E.coli (EHEC/STEC)
• enteropathogenic E. coli (EPEC)
• enteroaggregative E. coli (EAEC)
• diffuse adherent E. coli (DAEC)

Question 77

What does enterotoxic E. coli (ETEC) cause?

Answer 77

• cholera-like toxin
• watery diarrhoea

Question 78

What does enteroinvasive E. coli (EIEC) cause?

Answer 78

• Shigella-like illness
• bloody diarrhoea

Question 79

What does enterohaemorrhagic or Shiga toxin-producing E. coli (EHEC/STEC) cause?

Answer 79

• causes the most problems
• E. coli O157 serogroup, shigatoxin/verotoxin
• 5-10% get haemolytic ureamic syndrome - loss of kidney function

Question 80

How does Clostridium difficile cause problems?

Answer 80

• usually lives in GI tract without problem
• if there is a dysbiosis (usually due to antibiotics) you go into intermediate dysbiotic state where there is more C. diff and more inflammation-tolerant commensals and less disturbance-sensitive commensals
• still chance for things to go back to normal
• if not, you get pathogen-induced disturbance (toxin production) and inflammation-derived metabolites

Question 81

How do we manage C. difficile? (3)

Answer 81

• isolate patient (very contagious)
• stop current antibiotics
• give vancomycin or metronidazole (odd - can cause C. diff as well as treating it)

Question 82

What are recurrence rates like for C. difficile?

Answer 82

• 15-35% after initial infection
• increasingly difficult to treat if recurrence occurs

Question 83

How do we cure C. difficile?

Answer 83

Faecal Microbiota Transplantation (FMT) - 98% cure