TB Lecture Slides 2024 PDF

Summary

These lecture slides discuss tuberculosis. They cover topics such as the immune response against Mycobacterium tuberculosis, MTB infection and disease, transmission, and subclinical TB.

Full Transcript

The immune
response against
Mycobacterium
tuberculosis

MBChB II
Dysfunction
module
 MTB infection and disease
1/3 of world population is infected (infection
does not equal disease)
– Latent MTB infection (LTBI), dormant bacilli
– Huge reservoir for future disease
Active infection= ‘tuberculosis’ (>9M new
cases/year, leading cause of death due to
bacterial infection, ±3M deaths /year)
Interplay between HIV and MTB
Multi‐drug resistant (MDR) or Extensive drug
resistant (XDR) strains on the increase
 MTB transmission

Spread by inhalation of small
aerosolized droplet nuclei
(coughing, talking or sneezing
Particles remain airborne for long
Inhaled, particles are deposited in the terminal airways. A single
cough can generate (up to 3000 infectious droplets from a single
cough and many more from sneezing)
Large respiratory droplets and fomites are not important sources of
MTB transmission
Transmission mostly occurs indoors after prolonged exposure and
multiple inocula. The risk of infection is determined by the
closeness of the contact (often household or institutional) as well as
the infectiousness of the source case (more in smear positive
cases, people with lung cavities if HIV negative. In HIV positives
transmission occurs also without cavities)
 MTB Infection and TB disease

Not all exposed people become infected (approx 1/3)
Not all transmission leads to persistent infection
Only 3‐5% of infected people become diseased within 12
months and 5‐15% in their lifetime
Impaired immunity may lead to TB disease: host genetic
factors (i.e. IFNγ receptor deficiency), HIV/AIDS,
malnutrition, alcoholism, renal failure,
immunosuppressive therapy and diabetes mellitus
 Proposed new paradigm of tuberculosis according to the International
Consensus for Early TB (ICE‐TB):including subclinical TB

Conceptual Macroscopic Symptoms and Microbiology Notes
states pathology signs

I. Mtb infection Absent Absent Absent Based on immune reactivity (pos TST
or IGRA)

II. Subclinical TB, Present (CXR or Absent Absent Historically ‘Closed TB’ or minimal TB
non‐infectious CT)

III. Subclinical Present (CXR or Absent Present (culture Approximately half of prevalent
TB, infectious CT) or PCR positive) infectious PTB

IV. Clinical TB, Present Present Absent Extrapulmonary TB, majority of
non‐infectious children, miliary TB, non‐cavitary
pulmonary disease

V. Clinical TB, Present Present Present ‘Active TB’, approximately 50% of
infectious prevalent TB.

Lancet Resp. Med. 2024: Coussens AK et al
 Subclinical TB

Bacterial burden in the lung
36 – 80% of prevalent TB is
subclinical/asymptomatic Detection limit

Subclinical Activ Relapse
Imaging: TB e TB

– CXR- subtle or minimal changes;
– 4% of general population in high-prevalence setting;
– 10% of close contacts
Microbiology: scanty or low positive GeneXpert test or liquid culture of
sputum samples
Progression:
– In high incidence setting: 0.8 - 1% per year of general population
– Close contacts 2-3%
– Subclinical TB: 10% in one year and 25% in 3 years
– vast majority of subclinical TB don’t progress but substantial % do
 Immune Diagnosis of MTB infection
Delayed type hypersensitivity
Tuberculin skin test, Mantoux test, PPD
test
Also multiple puncture tests like Tine,
Heaf tests
The stages of a delayed type hypersensitivity
reaction.
 New tests for MTB infection: interferon gamma
Figure 12‐25
release assays= IGRA’s

Overnight culture (whole blood
[Quantiferon] or peripheral blood
mononuclear cells (PBMC’s) [T‐
Spot.TB] in the presence of MTB
antigens
Rely on pre‐existing memory T
cells against MTB antigens
More specific that TST
Quantiferon test T‐Spot.TB test
As sensitive as TST
More expensive than TST (>10
US$)
Requires lab expertise
More standardized that TST
Require only one visit to health
care worker (i.e., can phone result
through)
Less useful in high incidence
settings
Naïve T cells differentiate into effector and
memory cells

Effector cells are
short‐lived
Interaction via
MHC/T cell Naïve
receptor T cell

Infected Each T cell has
macrophage or receptors that
other antigen Clonal expansion: Memory cells remain at
only recognize differentiated effector higher frequencies than
presenting cell one antigen cells, all with the same T naïve T cells with same
cell receptors. specificity, are long‐lived,
Different phenotypes provide protection and
develop (Th1, 2, 17, Treg are used for tests of prior
etc) exposure
 The role of cytokines in protection and
susceptibility to MTB Treg
Protection from
Immunopathology
Inhibits effective anti- TGFβ,
MTB responses IL-10
IL-10, IL-4, IL-5

Th2 Th1 Protection from
INF Immunopathology
Inhibits effective anti-
IL-10, IL-4, IL-12, IL-18, MTB responses
IL-5 IL-23,
IL-27 INF,
TNFα

Granuloma disintegration,
Protection from immunopathology Granuloma integrity,
Containment of Mtb

Mtb infected IL-23
macrophage
For illustration only Th17

Adapted from Ronacher et al: CYTOKINES IN PULMONARY TUBERCULOSIS
Multiple ways to subvert macrophage function
during MTB infection
Interference with
phagosome‐lysosome fusion

Prevention of phago‐
lysosome acidification

Decreased induction by IFN‐
gamma

Down‐regulation and
degradation of MHC class II

Lack of upregulation of co‐
stimulatory molecules
Pathogenesis: innate immune cells induce T cells
After infection via aerosol, alveolar macrophages and probably interstitial
dendritic cells (DCs), which have engulfed M.TB in the lung, migrate along two
routes:

Route 1:
Infected macrophages and DCs enter draining lymph nodes and stimulate
antigen‐specific T cells. The lung lesion plus these lymph nodes form the Ghon
complex.

‐Mycobacterial antigens from incapacitated phagocytes are presented to highly
professional antigen presenting cells (APCs), primarily DCs.

‐Infected macrophages undergo apoptosis

‐APC’s activate the following cells:
‐CD4+ T cells (via MHC class II)
‐CD8+ T cells (via MHC class I)
‐Unconventional T cells
‐with γ/δ T‐cell receptor instead of α/β
‐T cells with MHC class I like molecules of CD1 family
…Pathogenesis: innate immune cells induce T cells

Route 2:
Infected macrophages and DCs enter the lung parenchyma where they
initiate inflammatory foci to which blood monocytes are attracted.
Mononuclear phagocytes accumulate and serve as the starting point
for the formation of a granuloma orchestrated by T cells. The
granuloma is surrounded by a fibrotic wall, which separates it from the
surrounding tissue and its center becomes necrotic. M.tb is now
contained and dormant, unable to cause disease until host is
weakened.
…Pathogenesis: the bug shuts down its metabolism, temporarily…
‐In the granuloma: hypoxic conditions. M.tb switches its gene expression from highly
active, replicative to dormancy (DosR regulon). No growth, reduced respiration and
metabolism. Become non‐stainable by conventional methods like Ziehl Neelsen acid fast
stain.

‐Once the lesion is disrupted: M.tb synthesizes RNA and DNA, divide, become
resuscitated. M.tb releases resuscitation promoting factor s (RPF’s) secreted by a few
metabolically active bugs‐ act as pheromones for dormant bacteria. These rpf’s are
enzymes that dissolve cell walls.

‐MTB then flourishes in liquefied lesion and is transmitted through blood stream or
airways to other parts of the body.

Multiple caseating
granulomas in the lung
 So, what goes wrong with the adaptive
immune system in TB? Loss of immune
memory
MTB changes antigens: Naïve or memory T cells become effector
T cells when they encounter their antigen. Effector cells that are
generated during early infection keep things in check but are not as
long lived as memory cells and decrease over time. MTB has 4000
genes, can change antigen expression, making memory cellsfrom
initial stage of infection useless.

Exhaustion of memory: persistent antigen coupled with strong
stimulation also leads to loss of memory cells (to counter
immunopathology).
 So, what goes wrong with the adaptive
immune system in TB? Misbalanced T
cell phenotypes

‐Th1 cells are needed (produce IFNγ, TNFα, IL‐12 etc) for
effective control of MTB infection.

‐Th2 cells(produce IL4, IL5, IL‐10, IL‐13, etc) and regulatory T
cells (produce IL‐10, TGFβ) prevent immunopathology but also
suppress Th1 cells and if this balance is disturbed MTB may
escape immune control.
The pathology of tuberculosis
 Antigen presenting cell (i.e. macrophage)

Granuloma formation

Antigen Epitheloid cell (activated
Giant cell macrophages)
Lymphocyte

Macrophage
Monocytes Fibroblast
Ghon focus

Ghon
complex
 M. tuberculosis infection

Primary tuberculosis
(Ghon focus + hilar nodes= Ghon complex)

Primary progressive TB Subclinical infection, possibly
in fibrotic granuloma (‘latent
infection’)

Reactivation during immune
suppression

Secondary/post‐primary TB
Secondary TB with
cavity formation in
upper lobe.

Ghon focus is a
fibrotic, calcified
lesion.
A cavity can break through
into a bronchus and
infectious material is then
disseminated throughout
the bronchial tree, causing
bronchopneumonic TB.
Cavities that
have broken
through into a
bronchus with
bronchogenic
spread of TB
Endobroncheal spread can cause
laryngeal or tracheal TB or
contralateral lung TB
Erosion into blood vessels can lead to
bleeding and hemoptysis. Although the
pulmonary arterial system is shown on the
left, the bronchial arterial system is most
often involved in life‐threatening hemoptysis
(comes from aorta).
Breakthrough into
pulmonary arteries
leads to segmental
miliary TB‐
characterized by a
large number of
millet‐like (2mm
mean, 1‐5 mm
range) nodules.
 Breakthrough into
pulmonary veins goes
through left ventricle
and to rest of body,
including to meninges,
liver, spleen, bone
marrow and other
http://www.patho.hku.hk
organs, also as miliary
TB. Often in young
children, immune
compromised patients
(HIV co‐infected,
diabetes, the elderly).
Spinal TB: hematogenous
dissemination can present as cold
abscess and can lead to severe
deformities and even paraplegia.
 TB’s effect on tissues
‐Destruction of tissue:
‐Acute: loss of function of involved organs
‐Chronic sequelae: bronchiectasis with secondary infections
‐Granulomas: act as space‐occupying lesions, i.e. in brain
‐Induces fibrosis
‐in hollow organs‐ GIT: obstruction; Fallopian tubes: infertility
‐in destroyed tissues: scarring with further loss of function
‐in body cavities (pleura, pericardium, peritoneum,
meninges): loss of function, obstruction, restriction
‐Destroys blood vessels: leads to hemorrhage
‐Cavities in lungs: aspergillomas (results in hemorrhage)
Secondary TB pathogenesis
Apical lesions
Lymphatic
Cavitation (’open TB’) vessels
Breaks through branch
Cough or gravity of pulm vein R heart

Pulm artery Pulm artery
Inhale Swallow Spread to Left heart and
trachea/larynx systemic circulation
Lung segment Whole lung

‐Bronchogenic Intestinal Endotracheal Disseminated TB, Miliary TB restricted
dissemination TB or laryngeal TB miliary TB or to lung
‐Bronchopneumonia extraplumonary TB
‐Pleural spread