Infection & Immunity Tutorials (BBS3024) 2024-2025 PDF

Summary

These tutorials cover the topics of infection and immunity, including the evolution of viruses, case studies on COVID-19 and HIV, and commensal microbes. The materials are geared toward biomedical science undergraduates at Maastricht University. The document discusses different types of bacteria.

Full Transcript

Infection & Immunity
BBS3024

Academic year: 2024–2024

Basic Challenge 3

Evolution of viruses

Faculty of Health, Medicine and Life Sciences
Bachelor Biomedical Science

 2017 Maastricht University, Faculty of He alth, Medicine and Life Sciences.
Nothing in this publication may be reproduced and/or made public by means of printing, offset, photocopy or microfilm
or in any digital, electronic, optical or any other form without the prior written permission of the owner of the
copyright.
 Faculty of Health, Medicine and Life Sciences

The Trick.
"Any virus that can cause disease in humans must have at least one immune evasion mechanism—at least one
immune evasion “trick.” Without the ability to evade the immune system, a virus is usually harmless. Understanding
immune evasion by a virus is frequently important for understanding the pathogenesis of the virus, as well as
understanding challenges faced by the adap ve immune system and any candidate vaccine."
Literature:
Se e A, Cro y S. Adap ve immunity to SARS-CoV-2 and COVID-19. Cell. 2021;184(4):861-880. doi:10.1016/j.cell.2021.01.007

Case COVID 19.

A 48-year-old man presents to the emergency department, referred by his family doctor due to fever and significant
shortness of breath. He has experienced flu-like symptoms for the past three days—fever, muscle aches, sore throat,
runny nose, and cough—coupled with progres-sive shortness of breath that has not responded to oral an bio cs
(amoxicillin). Notably, he reports a recent loss of smell and taste.
The pa ent's medical history reveals obesity (body mass index: 31 kg/m²) and a long history of smoking—one pack of
cigare es per day for 25 years, along with vaping for the last three years. He has not received vaccina ons for
influenza A and B or for SARS-CoV-2. In his community, several individuals are exhibi ng similar flu-like symptoms.
On physical examina on, he has fever and exhibits signs of dyspnea and tachypnea, with a rapid pulse and normal
blood pressure. Ausculta on reveals bilateral lung involvement con-sistent with pneumonia. He requires
supplemental oxygen at 5 liters per minute via nasal can-nula to maintain acceptable oxygen satura on levels.
A nasopharyngeal swab tests posi ve for SARS-CoV-2 via polymerase chain reac on (PCR), with a cycle threshold (CT)
value of 22, while tests for influenza and parainfluenza viruses are nega ve. Laboratory results indicate signs of
systemic inflamma on. Imaging studies, includ-ing chest X-ray and CT scan, reveal diffuse bilateral pneumoni s
without lung emboli.
The medical team diagnoses him with severe COVID-19 pneumonia. They ini ate treatment with intravenous
dexamethasone and tocilizumab to manage the inflammatory response. Ad-di onally, they deliberate on further
therapeu c op ons, including remdesivir, nirma-trelvir/ritonavir, molnupiravir, monoclonal an bodies, or
convalescent plasma. They also plan to assess his blood serum for the presence of an bodies against SARS-CoV-2,
which may in-form his immune status.

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 Faculty of Health, Medicine and Life Sciences

Case HIV
A 32-year-old woman is referred by her family doctor to the emergency department because of high fever, flu-like
symptoms, cervical lymphadeni s, and a skin rash. Her previous medical history is unremarkable. On physical
examina on she appears ill. Temperature 39.0⁰ Celsius, blood pressure 120/80 mmHg and pulse rate 94/minute. Her
tonsils are enlarged. Cervical, axillary and inguinal lymph nodes are enlarged and elas c on palpa on. Blood results
show lymphocytopenia. Serology is posi ve for an acute HIV (human immunodeficiency virus) infec on, Fiebig stage
3. The consulted infec ous diseases specialist recommends the pa ent to start combina on an retroviral therapy
(cART) immediately. However, the pa ent is in doubt and wonders why she can’t wait to see how the infec on
evolves and if her immune system can cure the infec on. Next to this, she wants to know if HIV, like covid-19, also has
a lot of variants.

Compare and constrast: SARS-CoV2 and HIV

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Tutorials
Infection & Immunity
BBS3024

Academic year: 2024–2025

Basic Challenge 1
Commensal Microbes – with a little help from our (little) friends

Faculty of Health, Medicine and Life Sciences
Bachelor Biomedical Science

 2017 Maastricht University, Faculty of He alth, Medicine and Life Sciences.
Nothing in this publication may be reproduced and/or made public by means of printing, offset, photocopy or
microfilm or in any digital, electronic, optical or any other form without the prior written permission of the
owner of the copyright.
 Faculty of Health, Medicine and Life Sciences

Basic Challenge 1
Commensal Microbes – with a little help from our (little) friends

Samira is a healthy and ambitious student who is fascinated by the tiny living organisms
residing on and inside of us – microbes.

Which microbes do you recognize in the figure below?
What do you still know about the structure and classification of bacteria?

Do microbial ecosystems differ across body sites? Why?

Figure 33.2 (Prescot’s Microbiology 12th edition)

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 Faculty of Health, Medicine and Life Sciences

She is particularly intrigued by the many functions that all these billions of microbes
have on us as a host and how we can manipulate them for our own well-being. To
maintain her own balanced and healthy microbiota, she puts quite some effort in a
healthy lifestyle. She finds this even more important after her recent delivery of her first
child. Unfortunately, Samira had to take several courses of antibiotics during pregnancy
and labor and finally had to undergo a cesarean section. She is now very worried that
her newborn might not be colonized by a healthy microbiota on its different body sites
due to these artificial circumstances. She is afraid that the microbiota function might be
impaired and her child might develop dysbiosis-related diseases or that her child’s
commensal microbes cannot keep opportunistic or strict pathogenic microbes at
bay.

Therefore, she is even more eager to allow her newborn child to have a lot of contact
with nature and provide optimal nurture for a positive impact on the microbial
communities to be developed across the different body sites. Still, she is wondering if
there was an additional option to compensate for the antibiotics and the artificial
way of delivery. Her curiosity led her to delve into the literatur where she found
evidence on different interventions, such as probiotics and vaginal swabs or fecal
microbiota transplantation (FMT).

The table below depicts several different bacteria and infections they can cause. Could
you reason whether they should be considered opportunistic or true pathogens and why?
Which infections might be the result of a dysbiotic microbiome?

Bacterium/bacterial Infec on Opportunis c or Related to
TCDB community true pathogen? dysbiosis?
exotoxins
>
- sporulation Clostridioides difficile An bio c-induced coli s opp?
Salmonella enterica serotype foodborne salmonellosis
Typhimurium true
E. coli urinary tract infec on opportunistic
hemolytic Streptococcus pneumoniae Secondary bacterial
?
capsule
- macrophage
resistant
pneumonia following
respiratory viral infec on opp
Bifidobacterium (formerly bacterial vaginosis
Gardnerella) vaginalis opportunistic

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 (sporulation
bacterial cells
endospores
-dormant in number
of
-no
increase cells
1. What are the Different Types of Bacteria (Gram-Positive vs. Gram-Negative)? nutrient
Overview:
depletion

struct are
o Bacteria are categorized into Gram-
Ngramt
positive and Gram-negative based on their cell wall
spheres
·
structure, a classification established by the Gram
rods staining technique. This distinction reflects differences
·

spiral shapes in their chemical composition, structure, pathogenic
potential, and antibiotic susceptibility. by transpeptidase
↓ penicillin
>
-

Gram-Positive Bacteria: binding proteins

·thin filaments
o Cell Wall Structure:
Nage Nam Peptidecross-linking ains
fimbriae adhesion
▪ Thick peptidoglycan layer (20-80 nm): This rigid
>
-

>
-

filaments pilli (sex pillus
long
>

structure provides physical support and
-

·

types pilli-movement
>

protection. The thickness of the peptidoglycan
-

·

flagella movement
-

layer is what enables Gram-positive bacteria to
retain the crystal violet stain, giving them a
capsule thick binds topeptide
a
-
purple color under the microscope. teichoic
outer layer
adherence to each
>
-
▪ Teichoic and lipoteichoic acids: These acids are lipoteichoic
other embedded in the cell wall and contribute to its in plasma
rigidity. They also help bacteria adhere to host memprane
70S ribosomes
tissues, initiate infections, and elicit immune
305550S
responses.
cytoplasm/membrane ▪ Absence of outer membrane: Without an outer

no nucleus membrane, Gram-positive bacteria are more
supercoiled DNA susceptible to certain antibiotics (e.g., penicillin,
>
-

nucleoid/plasmid which targets peptidoglycan synthesis).

plasmidshotals
is
o Examples:

▪ Staphylococcus aureus: Commonly found on the
et
skin and nasal passages; can cause a variety of
circular/linear
antibiotic
resistance
have
- can be shared
 infections, from superficial skin infections to life-
threatening diseases like endocarditis.
▪ Staphylococcus epidermidis: Part of the skin

microbiome, generally non-pathogenic but may
cause infections in individuals with weakened
immune systems or invasive medical devices
(e.g., catheters).
▪ Lactobacillus species: Play a vital role in the

gastrointestinal and genitourinary tracts by
producing lactic acid, which maintains an acidic
environment and inhibits pathogen growth.
o Function in Microbiomes:

▪ In environments like the skin, Gram-positive

bacteria form a protective barrier against
pathogens, assist in wound healing, and
contribute to the skin’s acidic pH.
▪ In the vagina and gut, Lactobacillus species

produce lactic acid to maintain low pH, inhibiting
pathogens and protecting against infections such
as bacterial vaginosis.
to antibiotics
Gram-Negative Bacteria: more resistant

o Cell Wall Structure:

▪ Thin peptidoglycan layer: Located between the

inner and outer membranes, this thin layer does
not retain the crystal violet stain and thus appears
pink or red after counterstaining.

lipid accharide
▪ Outer membrane with lipopolysaccharides

(LPS): The LPS component is a
t
powerful endotoxin that can cause strong
immune responses. LPS is a major virulence
factor, and in severe infections, it can lead
to septic shock.
 hydrophilic Porin channels: Embedded in the outer
▪
molecules enter
membrane, these channels regulate the entry of
can

·

periplasmic space nutrients and antibiotics, often contributing to
antibiotic resistance.
o Examples:

▪ Escherichia coli: A key member of the gut

microbiome, assisting in nutrient absorption,
vitamin synthesis, and metabolism. However,
pathogenic strains (e.g., E. coli O157
) can cause foodborne illnesses and severe
urinary tract infections.
▪ Bacteroides fragilis: Predominantly

anaerobic, Bacteroides species are crucial in bile
acid metabolismand complex carbohydrate
breakdown. Though typically commensal, they
can cause abscesses if they escape the gut
environment.
▪ Pseudomonas aeruginosa: An opportunistic

pathogen known for its role in hospital-acquired
infections, particularly in immunocompromised
patients or those with cystic fibrosis.
o Function in Microbiomes:

▪ Gut microbiome: Many Gram-negative bacteria

are essential for carbohydrate
fermentation, SCFA production, and
modulation of immune responses.
▪ Colonization resistance: By occupying ecological

niches in the gut, Gram-negative bacteria help
prevent colonization by pathogenic bacteria.

2. Opportunistic vs. True Pathogens vs. Commensal Bacteria
 Overview:
o Bacteria in the human body interact with the host in

varying ways, which are influenced by the host’s
immune status, microbiome composition,
and environmental conditions. These interactions can
classify bacteria as true pathogens, opportunistic
pathogens, or commensal bacteria.
True Pathogens:

o Characteristics:

▪ True pathogens possess inherent virulence factors,

enabling them to cause disease in healthy
individuals, regardless of immune status.
▪ They actively invade host tissues, evade immune

responses, and can disseminate to various organs.
o Examples:

▪ Mycobacterium tuberculosis: Causes tuberculosis,

an airborne infection where the bacteria survive
and replicate within host macrophages, evading
immune detection.
▪ Salmonella typhi: Causes typhoid fever; can

survive gastric acidity and penetrate the intestinal
mucosa, entering the bloodstream and lymphatic
system.
o Mechanism:

▪ These pathogens often possess specialized factors,

like toxins or invasion proteins, that directly
damage host tissues or impair immune defenses.
Opportunistic Pathogens:

o Characteristics:

▪ Normally non-pathogenic and may even benefit the

host. However, when host immunity is
 compromised (due to factors like stress,
antibiotic use, or underlying disease),
opportunistic pathogens can exploit these
conditions to cause disease.
o Examples:

▪ Staphylococcus epidermidis: A common skin

commensal that can cause infections in
immunocompromised patients or individuals with
indwelling medical devices.
▪ Escherichia coli: A gut commensal; certain strains

can cause urinary tract infections (UTIs) when
they enter the urinary tract.
o Role in Microbiome and Disease:

▪ Opportunistic pathogens are implicated

in antibiotic-associated colitis (e.g., Clostridium
difficileovergrowth following antibiotic
therapy), bacterial vaginosis (overgrowth of
anaerobes like Bifidobacterium vaginalis due to
disrupted vaginal pH), and UTIs.
Commensal Bacteria:

o Characteristics:

▪ Commensals are naturally occurring, generally

non-harmful bacteria that coexist with the host
and often provide benefits, such as aiding
digestion or preventing pathogen colonization.
▪ Through colonization resistance, commensals

occupy niches and compete for nutrients, helping
prevent the establishment of pathogens.
o Examples:

▪ Lactobacillus in the vaginal and intestinal

microbiomes helps maintain a low pH, creating
 an environment hostile to pathogens.
▪ Staphylococcus epidermidis on the skin provides

a natural barrier against pathogenic bacteria.
o Clinical Importance:
▪ The disruption of commensal bacteria can lead

to dysbiosis, where a reduction in commensals
can facilitate pathogen overgrowth, contributing
to conditions like bacterial vaginosis and certain
gastrointestinal infections.

3. Where are They Located, and Why?
Skin Microbiome:
o Location: Found on the outer epidermis, sebaceous

glands, and hair follicles.
o Environment: Relatively dry and mildly acidic with

regions of high lipid content (sebum).
o Primary Bacteria: Staphylococcus

epidermidis, Propionibacterium acnes.
o Role:

▪ Produces antimicrobial compounds (e.g.,

bacteriocins) that prevent pathogenic
colonization.
▪ Helps regulate the skin’s immune response and

maintains a low pH, inhibiting harmful bacteria
like Staphylococcus aureus.
Respiratory Tract Microbiome:

o Location: Nasal passages, throat, and lungs.

o Environment: Moist with variable pH and oxygen

levels.
o Primary
 Bacteria: Streptococcus and Neisseria species.
o Function:

▪ Helps trap inhaled pathogens and particles, with

mucociliary clearance supporting bacterial
removal.
▪ Respiratory commensals can modulate immune

responses, reducing inflammation and protecting
lung tissue.
Gastrointestinal Tract Microbiome:

o Location: Stomach, small intestine, and colon.

o Environment: Nutrient-rich with a gradient in pH

(acidic stomach, neutral intestines) and a low-oxygen
environment in the colon.
o Primary

Bacteria: Bacteroides, Lactobacillus, Escherichia
coli, Bifidobacterium.
o Role:

▪ Facilitates carbohydrate and protein

fermentation, producing short-chain fatty acids
(SCFAs) like butyrate, propionate, and acetate,
liver
which provide energy to colon cells and maintain
↓
gut health.
Gile acids
primary ▪ Plays a role in bile acid metabolism, breaking
emodified by microbes
↳ secondary file acids
down bile acids that regulate lipid absorption and
↳ modulatethe microbes
have antimicrobial properties.
▪ Aids in vitamin synthesis (e.g., vitamins B and K)

and bolsters immune defenses against pathogenic
bacteria.
Genitourinary Tract Microbiome:

o Location: Primarily the vagina and, to a lesser extent,

the urethra.
 o Environment: Acidic pH (especially in the vagina),
largely anaerobic.
o Primary Bacteria: Lactobacillus and, in cases of
bacterial vaginosis, overgrowth of Bifidobacterium
vaginalis.
o Role:
▪ Lactobacillus species maintain an acidic pH, which

prevents colonization by potential pathogens.
▪ An imbalance can lead to bacterial vaginosis,

which is characterized by an overgrowth of
anaerobic bacteria.

4. What is the Function of the Gut Microbiome (Bacterial Metabolism and
Immunity)?
The gut microbiome is integral to maintaining metabolic and
immune balance in the human body. It performs complex
functions that support digestion, produce essential metabolites,
influence immune development, and guard against pathogens.
Metabolic Functions:

o Short-Chain Fatty Acid (SCFA) Synthesis:

▪ Process: SCFAs, primarily acetate, propionate, and

butyrate, are produced during the fermentation of
dietary fibers and complex carbohydrates by gut
bacteria, particularly by members
of Bacteroidetes and Firmicutes phyla.
▪ Role:

▪ Energy Source: Butyrate serves as the

primary energy source for colonocytes,
aiding in intestinal barrier integrity.
▪ Anti-inflammatory Effects: SCFAs influence

immune cells, promoting anti-inflammatory
 cytokine production and suppressing pro-
inflammatory pathways. Butyrate, in
particular, inhibits histone deacetylases,
which has been linked to reduced
inflammation.
▪ Systemic Health: SCFAs can enter

circulation and impact peripheral tissues,
including the liver, where they influence
lipid metabolism, glucose homeostasis, and
insulin sensitivity.
o Carbohydrate and Protein Fermentation:
▪ Process: Through fermentation, gut bacteria break

down non-digestible carbohydrates, proteins, and
peptides into gases and organic acids.
▪ Role:

▪ Gaseous Byproducts: Hydrogen, carbon

dioxide, and methane gases are generated,
which may affect gut motility and contribute
to the gut’s microbial community structure.
▪ Protein Metabolism: Certain gut bacteria

degrade amino acids into byproducts like
indole, ammonia, and hydrogen sulfide.
These can exert toxic effects on the gut
lining if overproduced, as seen in dysbiosis.
o Bile Acid Metabolism:
▪ Primary and Secondary Bile Acids: Primary bile

acids are synthesized in the liver and modified by
gut bacteria into secondary bile acids (e.g.,
deoxycholic acid).
▪ Role:

▪ Fat Digestion: Bile acids are crucial for

emulsifying dietary fats, allowing
 absorption.
▪ Antimicrobial Action: Secondary bile acids

create an environment that prevents
overgrowth of pathogenic bacteria.
Additionally, specific bacteria
like Bacteroides regulate bile acid
modification, impacting lipid metabolism

methanogenesis
and glucose regulation in the host.
▪ Gut Integrity: Bile acids also signal to gut

epithelial cells to maintain mucosal integrity
and balance inflammation.
Immune Functions:

o Colonization Resistance:

▪ Mechanism: The microbiome provides

“colonization resistance” by competing with
pathogens for nutrients and attachment sites and
by producing antimicrobial compounds like
bacteriocins.
▪ Example: In the

gut, Bacteroides and Lactobacillus species
prevent colonization by pathogens such
as Clostridium difficile, which can overgrow if
commensals are diminished, as seen in antibiotic-
associated colitis.
o Modulation of the Immune System:

▪ Development of Immune Tolerance: Early-life

interactions between gut bacteria and the host’s
immune cells aid in “educating” the immune
system to tolerate beneficial microbes while
remaining responsive to pathogens.
▪ Regulation of Inflammation: The microbiome

helps maintain a balance between pro-
 inflammatory and anti-inflammatory
responses. Bifidobacterium and Lactobacillus pro
mote regulatory T-cells, which suppress
excessive immune responses, reducing risk of
inflammatory bowel disease (IBD) and allergies.
▪ Pathogen Defense: Certain microbes stimulate the

production of mucins, antimicrobial peptides, and
IgA antibodies that collectively enhance the gut’s
defense barrier.

5. How Do We Acquire Our Commensal Bacteria?
The process of acquiring a stable microbiome begins at birth and
continues to evolve through interactions with diet, environment,
and lifestyle.
Birth Mode:

o Vaginal Birth: Infants born through the vaginal canal

are exposed to maternal vaginal and intestinal
microbiota, such as Lactobacillus, Bacteroides,
and Bifidobacterium. This initial exposure provides
infants with protective bacteria that colonize the gut
and support early immunity.
o Cesarean Section (C-Section): C-section-delivered

infants primarily acquire skin-associated bacteria,
including Staphylococcus, Corynebacterium,
and Propionibacterium, which may lack some of the
beneficial gut-colonizing species found in vaginal
births. Studies have shown that C-section delivery can
lead to delayed microbial diversity, with increased
risks for immune-mediated conditions such as
allergies and asthma.
Infant Feeding:

o Breastfeeding: Breast milk contains oligosaccharides
 that act as prebiotics, selectively nourishing beneficial
bacteria like Bifidobacterium infantis. Breast milk also
contains immune factors (e.g., IgA, lactoferrin) that
help shape a protective microbiome and prevent
pathogenic colonization.
o Formula Feeding: While formula lacks the unique

oligosaccharides and antibodies in breast milk, many
formulas are now enriched with prebiotics and
probiotics to support a more balanced microbiome.
Environmental Exposure:

o Early-Life Interactions: Exposure to family members,

pets, and other environmental factors plays a
significant role in microbiome diversification.
Children raised in rural or farm environments tend to
develop more diverse microbiomes with reduced
allergy and asthma risks, potentially due to increased
microbial exposure.
o Antibiotic Exposure: While sometimes necessary,

early antibiotic use can disrupt the natural microbial
colonization process, sometimes leading to reduced
microbial diversity and a higher susceptibility to
infections and allergic diseases.
Dietary Transitions and Lifestyle:

o Introduction of Solid Foods: Introducing a varied diet

with fibers promotes the growth of bacteria involved
in complex carbohydrate digestion,
including Bacteroides and Firmicutes, enhancing
SCFA production.
o Lifestyle Factors: As individuals age, lifestyle factors

such as diet, exercise, stress, and travel continue to
influence the microbiome’s composition and health-
related functions.
 6. How Can We Manipulate Our Commensal Microbiome for Our Well-Being?
The composition and function of the microbiome can be
modified to enhance health, reduce disease risk, and manage
certain conditions.
Dietary Modifications:

o Fiber-Rich Diets: Diets high in dietary fiber from

fruits, vegetables, legumes, and whole grains promote
the growth of SCFA-producing bacteria
like Bifidobacterium and Lactobacillus and increase
butyrate production, which has anti-inflammatory
effects.
o Polyphenols and Fermented Foods: Foods rich in

polyphenols (e.g., berries, green tea) and fermented
foods (e.g., yogurt, kimchi) support the growth of
beneficial bacteria, enhancing gut barrier integrity and
reducing inflammation.
Prebiotics:

symbolis
o Definition and Function: Prebiotics are non-digestible

fibers that selectively stimulate the growth of
beneficial bacteria. Common prebiotics include inulin,
fructooligosaccharides (FOS), and
galactooligosaccharides (GOS).
o Health Benefits: Prebiotics enhance the growth

of Bifidobacterium and Lactobacillus, leading to
increased SCFA production, improved immune
modulation, and reduced risk of metabolic disorders.
Probiotics:

o Definition: Probiotics are live microorganisms that,

when ingested in adequate amounts, confer health
benefits by promoting a healthy balance of gut
bacteria.
 oCommon Strains: Lactobacillus
acidophilus, Bifidobacterium bifidum,
and Saccharomyces boulardii.
o Health Effects: Probiotics are used to treat conditions

like antibiotic-associated diarrhea, irritable bowel
syndrome (IBS), and inflammatory bowel disease
(IBD) by reducing inflammation, enhancing gut
barrier function, and competing with pathogens.
Fecal Microbiota Transplantation (FMT):

o Process: FMT involves transferring stool from a

healthy donor to a patient with severe dysbiosis, most
commonly for recurrent Clostridium difficile infection.
o Benefits: FMT can restore microbial diversity and

resilience in the gut, reducing symptoms and
preventing recurrence of infection.

7. How is Our Commensal Microbiome Disrupted (Dysbiosis)?
Dysbiosis is a disruption in the balance and diversity of the
microbiome, often associated with various diseases. It can be
triggered by factors such as antibiotic overuse, diet, and stress.
Causes of Dysbiosis:

o Antibiotic Use: Antibiotics, especially broad-spectrum

types, can indiscriminately kill beneficial bacteria,
leading to reduced diversity and a shift in microbial
balance. This can increase susceptibility to infections,
including overgrowth of antibiotic-resistant pathogens
like Clostridium difficile.
o Poor Diet: Diets high in sugar and low in fiber can

reduce beneficial bacteria
like Bifidobacterium and Lactobacillus, increasing
inflammation and promoting the growth of
pathobionts (disease-associated microbes).
 Stress and Lifestyle: Chronic stress and lack of sleep
o

can influence gut barrier integrity and reduce
microbial diversity, promoting conditions like irritable
bowel syndrome (IBS) and inflammatory bowel
disease (IBD).
Diseases Associated with Dysbiosis:

o Metabolic Syndrome: Dysbiosis is linked to obesity,

insulin resistance, and inflammation due to decreased
SCFA production and changes in bile acid metabolism.
o Inflammatory Bowel Disease (IBD): Loss of

beneficial species and overgrowth of pro-
inflammatory bacteria contribute to chronic gut
inflammation.
o Colorectal Cancer: Dysbiosis may promote

carcinogenesis through increased production of toxic
metabolites and chronic inflammation.

motility
different microdes in different places
bacteria spread
> too slow -
overgrowth of >
-
to wrong places

-too fast >
-
under fed bacteria
 bacteriocins
microsius

colicins
Infection & Immunity
BBS3024

Academic year: 2024–2025

Basic Challenge 2
Evolution of bacteria
- the thin line between commensals and pathogens -

Faculty of Health, Medicine and Life Sciences
Bachelor Biomedical Science

 2017 Maastricht University, Faculty of He alth, Medicine and Life Sciences.
Nothing in this publication may be reproduced and/or made public by means of printing, offset, photocopy or microfilm
or in any digital, electronic, optical or any other form without the prior written permission of the owner of the
copyright.
 Faculty of Health, Medicine and Life Sciences

Basic Challenge 3:
Evolution of bacteria - the thin line between commensals and pathogens

What do you still recall from your previous courses?

Figure 1 - Source: Prescott’s Microbiology, 12th edition

Figure 2 - Source: Wikimedia commons

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 Faculty of Health, Medicine and Life Sciences

“Good and evil are so close as to be chained together in the soul.”
― Robert Louis Stevenson, The Strange Case of Dr. Jekyll and Mr. Hyde

conjugationa
transformation

Figure 3 - Source: Balasubramanian et al. Trends in Microbiology 2022 [in press]
https://doi.org/10.1016/j.tim.2022.02.003.

Figure 4 - Source: Balasubramanian et al. Trends in Microbiology 2022 [in press]
https://doi.org/10.1016/j.tim.2022.02.003.

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 Faculty of Health, Medicine and Life Sciences

Ready - set - fire ……Type III, IV and VI secretion systems

Figure 5 - Summary of known bacterial secretion systems. In this simplified view only the basics of each
secretion system are sketched. HM: Host membrane; OM: outer membrane; IM: inner membrane; OMP:
outer membrane protein; MFP: membrane fusion protein. ATPases and chaperones are shown in yellow.
Source: Tseng, TT., Tyler, B.M. & Setubal, J.C. Protein secretion systems in bacterial-host associations, and their
description in the Gene Ontology. BMC Microbiol 9 (Suppl 1), S2 (2009). https://doi.org/10.1186/1471-2180-9-S1-S2

Studying bacterial evolution

Figure 6 - Genetic map of the UPEC strain 536 chromosome.
The two inner circles represent all putative genes (pangenome), depending on ORF orientation. The third circle from the center gives
the scale. The fourth circle from the center shows the G + C distribution. Regions with a highly aberrant G + C content (greater than
or less than 2-fold standard deviation) are highlighted in red. The outermost circles show the result of a three-way genome comparison
with the UPEC strain CFT073 and E. coli MG1655 (K-12) genomes: blue, backbone genes (core genome) found in all three strains;
red, genes present in 536 and CFT073 but absent from MG1655; green, genes found in 536 only; orange, genes of 536, which are
present in CFT073 but located in a different genomic region. Pathogenicity and genomic islands (GEIs) are highlighted; flanking
tRNAs are given in brackets.
Source: Brzuszkiewicz E., et al. PNAS 2006:103(34)12879-12884 https://doi.org/10.1073/pnas.0603038103

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 1. How do the different types of antibiotics work, and how do bacteria resist
antibiotics?
Mechanisms of Antibiotic Action
Antibiotics target specific processes critical for bacterial survival
and replication. Understanding how each type works provides
insights into their effectiveness and limitations:
1. Inhibition of Cell Wall Synthesis:
o Beta-lactams (e.g., penicillins, cephalosporins):

▪ These antibiotics inhibit the synthesis of

peptidoglycan, an essential component of the
bacterial cell wall. They target penicillin-binding
proteins (PBPs), enzymes involved in the final
stages of assembling the cell wall and reshaping
it during cell growth and division.
▪ Without a properly formed cell wall, bacteria

cannot maintain osmotic balance, leading to cell
lysis.
▪ Example: Streptococcus

pneumoniae and Staphylococcus aureus are
susceptible to beta-lactams unless resistant
mechanisms are present.
o Glycopeptides (e.g., vancomycin):

▪ Vancomycin binds directly to the D-Ala-D-Ala

termini of peptidoglycan precursors, preventing
cross-linking. It is particularly effective against
Gram-positive bacteria like MRSA but ineffective
against Gram-negative bacteria due to its large
size and inability to penetrate the outer
 membrane.
2. Inhibition of Protein Synthesis:
o Aminoglycosides (e.g., gentamicin, streptomycin):

▪ These bind irreversibly to the 30S ribosomal

subunit, causing misreading of mRNA, leading
to defective proteins. The action is bactericidal,
especially against aerobic Gram-negative
bacteria.
o Tetracyclines:

▪ Tetracyclines bind reversibly to the 30S ribosomal

subunit, blocking the attachment of aminoacyl-
tRNA to the A site of the ribosome. This prevents
protein elongation. They are broad-spectrum
antibiotics used against Gram-positive and Gram-
negative bacteria, as well as atypical pathogens
like Chlamydia and Mycoplasma.
o Macrolides (e.g., erythromycin, azithromycin):

▪ These target the 50S ribosomal subunit,

specifically inhibiting translocation by blocking
the exit tunnel of the growing peptide chain. This
prevents elongation of the protein chain,
effectively halting protein synthesis. Macrolides
are commonly used for respiratory infections and
are effective against Gram-positive bacteria and
some Gram-negative bacteria.
o Chloramphenicol:

▪ Inhibits the peptidyl transferase activity of the

50S ribosomal subunit, preventing peptide bond
formation. Though effective, its use is limited
due to potential serious side effects like aplastic
anemia.
3. Inhibition of Nucleic Acid Synthesis:
 o Fluoroquinolones (e.g., ciprofloxacin, levofloxacin):
▪ These antibiotics inhibit bacterial DNA gyrase

(topoisomerase II) and topoisomerase IV,
enzymes crucial for supercoiling and uncoiling
DNA during replication and transcription. The
inhibition of these enzymes leads to DNA strand
breaks and ultimately bacterial cell death. They
are effective against a broad range of Gram-
negative bacteria and some Gram-positive
bacteria.
o Rifamycins (e.g., rifampin):

▪ Rifamycins bind to bacterial RNA polymerase,

blocking the initiation of RNA synthesis. This
prevents transcription, effectively inhibiting
bacterial replication and protein production.
Rifampin is commonly used to treat tuberculosis
and bacterial infections with Neisseria
meningitidis.
4. Disruption of Metabolic Pathways:
o Sulfonamides and Trimethoprim:

▪ These antibiotics inhibit enzymes involved in the

bacterial folic acid synthesis pathway, which is
crucial for nucleotide biosynthesis.
▪ Sulfonamides compete with para-aminobenzoic

acid (PABA) for the enzyme dihydropteroate
synthase, preventing the synthesis of
dihydrofolic acid.
▪ Trimethoprim inhibits dihydrofolate reductase,

blocking the conversion of dihydrofolic acid to
tetrahydrofolic acid, which is necessary for DNA
synthesis.
▪ These drugs are often used in combination (e.g.,
 cotrimoxazole) to enhance effectiveness and
prevent resistance.
Mechanisms of Antibiotic Resistance
Bacteria have evolved multiple strategies to evade the effects of
antibiotics. These mechanisms include both inherent resistance
and acquired resistance through genetic mutations or horizontal
gene transfer.
1. Enzymatic Degradation or Modification:
o Beta-lactamases:

▪ These enzymes hydrolyze the beta-lactam ring of

penicillins and cephalosporins, rendering them
inactive. There are several types of beta-
lactamases, including extended-spectrum beta-
lactamases (ESBLs) that confer resistance to a
broader range of beta-lactams, including third-
generation cephalosporins.
▪ Carbapenemases (e.g., KPC, NDM) can degrade

even carbapenems, which are often used as a last
resort for multidrug-resistant infections.
o Aminoglycoside-Modifying Enzymes:

▪ These enzymes add chemical groups (acetyl,

phosphate, adenyl) to aminoglycosides,
preventing their binding to the ribosome.
2. Modification of Target Sites:
o Alteration of PBPs:

▪ In Staphylococcus aureus, resistance to methicillin

(MRSA) is due to the acquisition of a modified
PBP2a, encoded by the mecA gene, which has a
low affinity for beta-lactams.
o Mutations in Ribosomal RNA or Proteins:

▪ Mutations in the 23S rRNA or ribosomal proteins
 prevent the binding of macrolides and other
ribosome-targeting antibiotics.
3. Efflux Pumps:
o Multidrug efflux pumps actively transport antibiotics

out of the bacterial cell, reducing intracellular
concentrations to sub-lethal levels. These pumps can
confer resistance to a wide range of antibiotics,
including tetracyclines, fluoroquinolones, and
macrolides.
o Example: The AcrAB-TolC efflux system in E. coli.

4. Reduced Permeability:
o Changes in porin proteins reduce the uptake of

antibiotics, particularly in Gram-negative bacteria. For
example, mutations in OmpF porins can confer
resistance to beta-lactams and fluoroquinolones by
limiting drug entry.
5. Biofilm Formation:
o Bacteria in biofilms are embedded in a protective

extracellular matrix that restricts antibiotic
penetration. Within biofilms, bacteria can exhibit a
slower growth rate and metabolic activity, making
them less susceptible to antibiotics that target rapidly
dividing cells.
6. Target Bypass:
o Some bacteria acquire alternative pathways or

redundant enzymes that bypass the inhibited pathway.
For example, resistance to trimethoprim can arise
through the acquisition of a plasmid-encoded
alternative dihydrofolate reductase enzyme.
7. Horizontal Gene Transfer (HGT):
o Resistance genes can spread through bacterial
 populations via transformation, conjugation,
and transduction:
▪ Transformation: Uptake of free DNA from the

environment.
▪ Conjugation: Transfer of plasmids or integrative

conjugative elements through direct cell-to-cell
contact.
▪ Transduction: Transfer of genetic material by

bacteriophages.
These mechanisms allow bacteria to adapt rapidly to antibiotic
pressure, posing a significant challenge to clinical management
of bacterial infections.

Vesiceaction
residuction
2. How do horizontal gene transfer and mobile elements work?
Horizontal gene transfer (HGT) is a critical process in bacterial
evolution, allowing the transfer of genetic material between
organisms without the need for reproduction. This mechanism
significantly contributes to genetic diversity and the rapid spread
of traits such as antibiotic resistance.
Mechanisms of Horizontal Gene Transfer (HGT):
1. Transformation:
o Transformation involves the uptake of naked DNA

fragments from the environment by a competent
bacterial cell. Competence refers to the cell's ability to
take up and incorporate exogenous DNA.
o Natural Competence: Some bacteria, such
 as Streptococcus pneumoniae and Bacillus subtilis, are
naturally competent. They possess specific proteins
that facilitate DNA uptake and integration into their
genomes.
o Induced Competence: In other bacteria, competence

can be induced under laboratory conditions using
treatments like calcium chloride or electroporation.
o Mechanism:

▪ DNA binding proteins on the bacterial surface

capture DNA fragments.
▪ The DNA is transported into the cell and integrated

into the bacterial chromosome by homologous
recombination.
▪ This process can introduce new traits, such as

antibiotic resistance or virulence factors, into the
bacterial population.
same replication
2. Conjugation:
enot compatible
o Conjugation is a process of direct transfer of DNA
plasmids
·

replicate between two bacterial cells, typically mediated by a
·
move conjugative plasmid.
·

regulate (limited copies
o F Plasmid (F Factor): The F plasmid in Escherichia
per bacterial

plasmid
encodes for
coli is a well-studied example. It carries the Tra
pilus operon, which encodes the proteins required for the
formation of a sex pilus and DNA transfer.
o Mechanism:

▪ A donor cell (F+) containing the F plasmid forms a

conjugation pilus to connect with a recipient cell
a secretion
type (F-).
system ▪ The pilus retracts, bringing the two cells into close

contact, forming a conjugation bridge.
relaxosome
▪ A single strand of the F plasmid is transferred to
 the recipient cell and replicated, converting the F-
cell into an F+ cell.
o Hfr Conjugation:

▪ Sometimes the F plasmid integrates into the

bacterial chromosome, forming an Hfr (high-
frequency recombination) cell.
▪ During conjugation, Hfr cells transfer

chromosomal genes along with plasmid genes to
the recipient, allowing for genetic recombination.
3. Transduction:
o Transduction is the process of DNA transfer mediated

by bacteriophages (viruses that infect bacteria).
o Generalized Transduction:

▪ In the lytic cycle, a phage infects a bacterial cell

and accidentally packages fragments of the host's
DNA into new phage particles.
▪ These defective phages can inject the bacterial

DNA into a new host cell, where it can recombine
with the recipient's genome.
o Specialized Transduction:

▪ Occurs in the lysogenic cycle when a temperate

phage integrates into the host genome as a
prophage.
▪ Upon excision, the phage may take adjacent

bacterial genes with it, transferring them to a new
host upon infection.
o Lytic vs. Lysogenic Cycle:

▪ Lytic Cycle: The phage replicates inside the host,

leading to cell lysis and release of new phages.
▪ Lysogenic Cycle: The phage DNA integrates into

the host genome, replicating along with it until
 induced to enter the lytic cycle.
Mobile Genetic Elements:
1. Insertion Sequences (IS):
o The simplest type of mobile genetic elements.

o Comprise a gene encoding transposase, flanked by

inverted repeat sequences.
o Transposase catalyzes the movement (transposition) of

the IS element within the genome.
o Function: They can disrupt genes or regulatory regions

when inserted, leading to mutations or altered gene
expression.
2. Transposons:
o Larger than IS elements and can carry additional genes,

such as antibiotic resistance genes.
o Composite Transposons: Consist of two IS elements

flanking a central region containing other genes.
o Unit Transposons: Do not have IS elements but carry

genes for transposase and additional functions.
o Transposons can move within the genome or between

DNA molecules, such as plasmids and chromosomes.
3. Integrative and Conjugative Elements (ICEs):
o Hybrid elements that can integrate into the bacterial

genome and excise to transfer between cells via
conjugation.
o Combine features of transposons (integration and

excision) and conjugative plasmids (transfer between
cells).
o Example: ICEs can carry genes for antibiotic

resistance, virulence, or metabolic pathways.
4. Recombinases:
 o Enzymes like transposases, integrases,
and resolvases facilitate the movement and integration
of mobile genetic elements.
o Transposases: Catalyze the excision and insertion of

transposons.
o Integrases: Mediate the integration of prophages into

bacterial genomes during lysogeny.
o Resolvases: Resolve cointegrates formed during

transposition events.
Impact of HGT and Mobile Genetic Elements on Bacterial
Evolution:
1. Genetic Diversity:
o HGT introduces new genetic material, increasing

variability and allowing bacteria to rapidly adapt to
environmental changes, such as the presence of
antibiotics.
2. Spread of Antibiotic Resistance:
o Resistance genes are often located on mobile genetic

elements like plasmids, transposons, or ICEs,
facilitating their transfer across different bacterial
species.
o This can lead to the rapid emergence of multidrug-

resistant strains, posing significant challenges to
treatment.
3. Virulence Factors:
o Genes encoding toxins, adhesion factors, and secretion

systems can be transferred via HGT, enhancing the
pathogenicity of recipient bacteria.
4. Comparative Genomics:
o Analysis of genomic islands, including pathogenicity

islands, reveals horizontal transfer events and the
 acquisition of adaptive traits.
o Core genome and pangenome studies highlight the

genetic diversity within bacterial species,
distinguishing essential genes from accessory genes
acquired through HGT.
In summary, horizontal gene transfer and mobile genetic
elements play pivotal roles in bacterial evolution, adaptation,
and the spread of important traits like antibiotic resistance and
virulence. Understanding these processes is crucial for
developing strategies to combat bacterial infections and prevent
the dissemination of resistance genes.
Direct repeats sticky ends
*

simple replicative
transposition : vs.

* look into conjugation ,
FT
, ,
,
F F ets.
depends on how long connected

3. How Can You Study the Evolution of Bacteria?
Studying bacterial evolution provides crucial insights into how
bacteria adapt to changing environments, develop resistance to
antibiotics, and enhance their virulence. This involves
examining genetic changes, horizontal gene transfer, and the
role of mobile genetic elements. Several methodologies and
concepts are essential in understanding bacterial evolution:
1. Comparative Genomics
Comparative genomics involves comparing the genetic material
of different bacterial strains or species to identify evolutionary
relationships and functional differences.
Core Genome vs. Pangenome:

o Core Genome: The set of genes shared by all strains of

a species. These genes are essential for basic cellular
functions and survival.
o Pangenome: Includes the core genome plus accessory

genes that are present in some but not all strains. The
pangenome reflects the genetic diversity within a
species and includes genes acquired through
horizontal gene transfer (HGT), which may confer
advantageous traits like antibiotic resistance or
virulence.
Genomic Islands:

o These are large segments of DNA acquired via HGT,

often containing genes that provide adaptive
advantages such as resistance to antibiotics, virulence
factors, or metabolic capabilities.
o Pathogenicity Islands are a specific type of genomic

island that carry genes contributing to a bacterium’s
ability to cause disease, such as toxins, adhesion
factors, and secretion systems.
G+C Content Analysis:

o Bacterial genomes have characteristic G+C content (the

percentage of guanine and cytosine bases). Variation
in G+C content can indicate the acquisition of foreign
DNA, as horizontally transferred genes often retain the
nucleotide composition of their original host.
2. Horizontal Gene Transfer (HGT) and Its Role in
Evolution
HGT plays a significant role in bacterial evolution by allowing
the transfer of genetic material between different organisms,
bypassing the traditional vertical transmission from parent to
offspring.
Mechanisms of HGT:

o Transformation: Uptake of free DNA from the

environment, integrating it into the genome.
o Conjugation: Direct transfer of DNA between bacteria

via cell-to-cell contact, often mediated by conjugative
plasmids.
o Transduction: Transfer of DNA by bacteriophages,

which can inadvertently package bacterial DNA
during their replication cycle.
HGT accelerates bacterial evolution by introducing genetic
variability, enabling rapid adaptation to environmental pressures
such as antibiotic treatment or immune system attacks.
3. Mobile Genetic Elements
Mobile genetic elements such as plasmids, transposons, and
integrative conjugative elements (ICEs) contribute to the
dynamic nature of bacterial genomes.
Plasmids: Circular DNA molecules that replicate

independently of the bacterial chromosome. They often
carry genes for antibiotic resistance or virulence factors.
Transposons and Insertion Sequences (IS): These

elements can move within and between genomes, spreading
genes that confer advantageous traits.
Integrative and Conjugative Elements (ICEs): These

elements integrate into the host genome and can excise to
transfer to other bacteria, combining the mobility of
plasmids and the integration ability of transposons.
4. Phylogenetic Analysis
Phylogenetic analysis helps trace the evolutionary relationships
among bacterial species or strains by comparing genetic
sequences.
 16S rRNA Gene Sequencing:
o The 16S rRNA gene is highly conserved across

bacterial species, making it a valuable tool for
reconstructing phylogenies and identifying
evolutionary lineages.
Whole-Genome Sequencing:

o Provides a comprehensive view of genetic differences,

revealing evolutionary relationships and the impact of
horizontal gene transfer.
Molecular Clocks:

o By estimating mutation rates, researchers can infer

divergence times and evolutionary rates, providing
insights into how quickly bacteria evolve under
different environmental pressures.
5. Adaptation to Antibiotics and Environmental Pressures
Antibiotic Resistance Evolution:

o Studying how bacteria acquire and spread resistance

genes sheds light on evolutionary pressures exerted by
antibiotic use.
o Comparative studies of resistant and susceptible

strains can identify genetic changes associated with
resistance.
Environmental Adaptation:

o Bacteria often acquire genes enabling them to survive

in diverse environments. Studying such adaptations
can reveal how bacteria evolve in response to specific
ecological niches or host environments.
6. Experimental Evolution
Laboratory Evolution Studies:

o Researchers can observe bacterial evolution in real-

time by subjecting bacteria to controlled
 environmental pressures, such as antibiotics or
nutrient limitations, over many generations.
o Lenski’s Long-Term Evolution Experiment

(LTEE): A famous example where E. coli populations
have been evolved for tens of thousands of
generations, revealing insights into adaptation,
mutation rates, and genetic diversification.
7. Genetic and Functional Studies
Mutagenesis and Gene Knockout Studies:

o By creating mutations or knocking out specific genes,

researchers can determine their role in bacterial
survival, adaptation, and virulence.
Transcriptomics and Proteomics:

o Studying changes in gene expression (transcriptomics)

and protein production (proteomics) under different
conditions can reveal how bacteria adapt to
environmental stresses and antibiotics.
8. Analyzing Evolutionary Pathways and Common
Ancestors
Ancestral Gene Reconstruction:

o Computational methods can infer the sequences of

ancestral genes, providing insights into the
evolutionary pathways and functions of modern genes.
Tracing Common Ancestors:

o By comparing genetic sequences across multiple strains

or species, researchers can identify common ancestors
and trace the evolutionary history of specific traits,
such as virulence or resistance.
Conclusion
Studying bacterial evolution involves a combination of
comparative genomics, experimental evolution, and molecular
techniques. It reveals how bacteria adapt, acquire resistance, and
evolve new functions. Understanding these processes is crucial
for developing strategies to combat antibiotic resistance and
predict bacterial responses to environmental changes.

4. What Are the Types of Virulence Factors and How Do They Function?
Virulence factors are specialized molecules or structures that
enable bacteria to colonize a host, evade or suppress the immune
system, obtain nutrients, and cause disease. These factors are
often encoded on mobile genetic elements like plasmids,
transposons, and pathogenicity islands, which facilitate their
horizontal transfer among bacterial populations. Understanding
virulence factors is crucial for developing strategies to prevent
and treat bacterial infections.
1. Secretion Systems
Bacterial secretion systems are specialized apparatuses used to
transport proteins or other molecules across bacterial
membranes into host cells or the surrounding environment.
These systems play critical roles in bacterial pathogenicity by
delivering effector proteins that manipulate host cellular
processes.
Type III Secretion System (T3SS):

o Found in Gram-negative bacteria

like Salmonella, Shigella, and Yersinia.
o Resembles a molecular syringe that injects effector

proteins directly into the host cell cytoplasm.
o These effector proteins can alter host signaling
 pathways, disrupt the cytoskeleton, and suppress
immune responses, facilitating bacterial invasion and
survival.
Type IV Secretion System (T4SS):

o Used by bacteria like Helicobacter

pylori and Legionella pneumophila.
o Capable of transferring both DNA and proteins. In H.

pylori, the T4SS injects the CagA protein into gastric
epithelial cells, promoting inflammation and
potentially leading to cancer.
Type VI Secretion System (T6SS):

o Found in pathogens like Pseudomonas

aeruginosa and Vibrio cholerae.
o Functions as a molecular spear, delivering toxic

effector proteins into competing bacteria or eukaryotic
host cells.
o T6SS can disrupt host immune cells or outcompete

other microbes in the same niche.
2. Adhesion Factors
Adhesion is the first step in the establishment of many bacterial
infections. Adhesins are surface molecules that enable bacteria
to attach to host cells or tissues, facilitating colonization and
subsequent infection.
Pili and Fimbriae:

o These are hair-like structures on the bacterial surface

that mediate attachment to host cell receptors.
o Type I fimbriae in E. coli enable adherence to urinary

tract epithelial cells, a key factor in urinary tract
infections.
Adhesins:

o Non-pilus adhesins like the MSCRAMMs (Microbial
 Surface Components Recognizing Adhesive Matrix
Molecules) bind to extracellular matrix proteins such
as fibronectin and collagen.
o Example: Staphylococcus aureus produces protein A,

which binds to host immunoglobulin G (IgG),
disrupting opsonization and phagocytosis.
3. Invasion and Dissemination Factors
Once attached, some bacteria invade host cells or tissues to
establish infections. This process often involves enzymes and
other proteins that break down host barriers or evade immune
detection.
Invasins:

o Bacterial proteins that trigger host cell uptake,

facilitating intracellular survival.
o Example: Listeria monocytogenes produces internalin,

which induces its uptake by epithelial cells.
Enzymes Facilitating Spread:

o Hyaluronidase: Degrades hyaluronic acid in the

extracellular matrix, allowing bacteria to penetrate
tissues.
o Collagenase: Breaks down collagen, aiding in tissue

invasion.
o Streptokinase: Converts plasminogen to plasmin,

dissolving blood clots and allowing bacteria to spread
through tissues.
4. Biofilm Formation
Biofilms are structured communities of bacteria encased in a
self-produced extracellular matrix that adheres to surfaces and
protects the bacteria from environmental stresses.
Biofilm Advantages:

o Enhanced resistance to antibiotics and immune
 responses.
o Example: Pseudomonas aeruginosa forms biofilms in

the lungs of cystic fibrosis patients, contributing to
chronic infections.
Biofilm Components:

o Exopolysaccharides form the primary matrix, trapping

nutrients and shielding bacteria from immune attacks.
o Biofilms can harbor persister cells that are dormant and

highly tolerant to antibiotics, making infections
difficult to eradicate.
5. Iron Scavenging Mechanisms
Iron is essential for bacterial growth, but in the host, free iron is
limited due to sequestration by host proteins like transferrin and
ferritin.
Siderophores:

ATP o High-affinity iron-chelating molecules secreted by

production bacteria to capture iron from host proteins.
o Example: Enterobactin produced by E. coli binds iron
requires
iron tightly and is then re-imported into the bacterial cell.
Direct Iron Acquisition:

o Some bacteria have receptors that directly bind host

iron-carrying proteins, extracting iron for bacterial
use.
6. Toxins
Bacterial toxins are categorized into exotoxins and endotoxins
based on their structure, function, and release mechanism.
Exotoxins:

o Soluble proteins secreted by bacteria that can cause

damage to host cells by various mechanisms.
o AB Toxins:
 ▪ Consist of two components: the A (active) subunit
and the B (binding) subunit.
▪ Example: Diphtheria toxin (produced

by Corynebacterium diphtheriae) inhibits protein
synthesis by ADP-ribosylating elongation factor-
2 (EF-2), leading to cell death.
o Membrane-Disrupting Toxins:

▪ Example: Hemolysins produced

by Streptococcus species lyse red blood cells to
release iron.
o Superantigens:

▪ These toxins cause an excessive immune response

by non-specifically activating T-cells.
▪ Example: Toxic shock syndrome toxin-1 (TSST-

1) from Staphylococcus aureus leads to a massive
release of cytokines, causing toxic shock.
Endotoxins:

o Components of the outer membrane of Gram-negative

bacteria, specifically the lipopolysaccharide
(LPS)layer.
o The Lipid A component of LPS is the toxic portion,

which, when released during bacterial lysis, triggers a
strong immune response.
o Endotoxins can cause septic shock, characterized by

fever, hypotension, and multiple organ failure.
7. Antiphagocytic Factors
Bacteria have evolved various mechanisms to avoid being
engulfed and destroyed by host phagocytes.
Capsules:

o Polysaccharide layers that cover the bacterial surface,

preventing phagocytosis.
 oExample: Streptococcus pneumoniae uses its capsule to
evade detection and destruction by the immune
system.
Protein A:

o Found in Staphylococcus aureus, it binds the Fc region

of antibodies, preventing opsonization and
phagocytosis.
Conclusion
Virulence factors are diverse and multifaceted, enabling bacteria
to effectively colonize hosts, evade immune defenses, and cause
disease. These factors include secretion systems for delivering
effector molecules, adhesion molecules for attachment, enzymes
for tissue invasion, biofilm formation for protection, iron
acquisition systems for survival, and toxins that directly damage
host tissues. Understanding these mechanisms is crucial for
developing targeted therapies and preventive measures against
bacterial infections.
resistance : intrinsic / acquired

5. What Genetic Mechanisms Do Bacteria Develop to Counteract Antimicrobial
Processes?
Bacteria have evolved a variety of sophisticated genetic
mechanisms to resist the effects of antimicrobial agents. These
mechanisms involve both intrinsic resistance and the acquisition
of resistance genes through horizontal gene transfer (HGT) and
mutations. Let’s delve into the detailed mechanisms by which
bacteria develop and propagate resistance to antibiotics.
1. Enzymatic Degradation or Modification of Antibiotics
Beta-lactamases:

o Beta-lactamases are enzymes that hydrolyze the beta-

lactam ring found in penicillins, cephalosporins, and
carbapenems, rendering these antibiotics ineffective.
There are various classes of beta-lactamases,
including:
▪ Class A Beta-lactamases: Include extended-

spectrum beta-lactamases (ESBLs), which can
hydrolyze third-generation cephalosporins.
▪ Class B Beta-lactamases (Metallo-beta-

lactamases): These enzymes require zinc for
activity and can hydrolyze carbapenems (e.g.,
New Delhi Metallo-beta-lactamase, NDM-1).
▪ Class C Beta-lactamases: Also known as AmpC

beta-lactamases, which confer resistance to a
broad range of beta-lactam antibiotics.
Aminoglycoside-Modifying Enzymes:

o These enzymes add chemical groups (acetyl,
 phosphate, or adenyl) to aminoglycosides, such as
gentamicin and tobramycin, preventing them from
binding to their target ribosomal subunit.
Chloramphenicol Acetyltransferase (CAT):

o This enzyme acetylates chloramphenicol, preventing it

from binding to the 50S ribosomal subunit and thereby
inactivating it.
2. Target Modification
Bacteria can develop mutations or acquire genes that alter the
target site of antibiotics, reducing the drugs’ binding affinity and
effectiveness.
Alteration of Penicillin-Binding Proteins (PBPs):

o In methicillin-resistant Staphylococcus

aureus (MRSA), the acquisition of the mecA gene
leads to the production of PBP2a, a penicillin-binding
protein with a low affinity for beta-lactams, thereby
conferring resistance.
Ribosomal Modifications:

o Mutations in 16S rRNA confer resistance to

aminoglycosides by preventing the drug from binding
to the 30S ribosomal subunit.
o Methylation of 23S rRNA by erm genes prevents

macrolides from binding to the 50S ribosomal subunit.
DNA Gyrase and Topoisomerase IV Mutations:

o Mutations in genes encoding DNA gyrase (gyrA) and

topoisomerase IV (parC) confer resistance to
fluoroquinolones by reducing drug binding to these
enzymes, which are essential for DNA replication.
3. Efflux Pumps
Efflux pumps are membrane proteins that actively expel
antibiotics from the bacterial cell, reducing intracellular
concentrations to sub-lethal levels.
Major Efflux Pump Families:

o Resistance-Nodulation-Division (RND)

Family: Found mainly in Gram-negative bacteria,
e.g., the AcrAB-TolC system in E. coli, which pumps
out a wide range of antibiotics, including tetracyclines,
fluoroquinolones, and beta-lactams.
o ATP-Binding Cassette (ABC) Transporters: Use

ATP hydrolysis to export antibiotics out of the cell.
o Major Facilitator Superfamily (MFS): Includes the

TetA pump, which confers resistance to tetracyclines
by expelling them from the cell.
4. Reduced Permeability
Bacteria, particularly Gram-negative species, can modify their
outer membrane to reduce the uptake of antibiotics.
Porin Modifications:

o Porins are channels that allow small molecules,

including antibiotics, to pass through the outer
membrane of Gram-negative bacteria.
o Decreased expression or mutations in porins

(e.g., OmpF in E. coli) reduce the uptake of beta-
lactams and fluoroquinolones, leading to resistance.
5. Biofilm Formation
Biofilms are structured communities of bacteria embedded in a
self-produced extracellular polymeric matrix. This matrix
protects bacteria from antibiotics and immune responses.
Biofilm Characteristics:

o Bacteria within biofilms are in a metabolically slow-

growing state, reducing the efficacy of antibiotics that
target actively dividing cells.
o The extracellular matrix acts as a physical barrier,
 preventing antibiotic penetration.
o Biofilms facilitate the horizontal transfer of resistance

genes among bacteria within the community.
6. Target Bypass
Bacteria can bypass metabolic pathways inhibited by antibiotics
by acquiring alternative enzymes or pathways.
Sulfonamide and Trimethoprim Resistance:

o Resistance arises from the acquisition of alternative

dihydropteroate synthase and dihydrofolate reductase
enzymes encoded by plasmid-borne genes
(sul and dfr), which are not inhibited by these drugs.
Vancomycin Resistance in Enterococcus (VRE):

o Vancomycin-resistant Enterococcus spp. acquire genes

(vanA, vanB) that alter the peptidoglycan precursor
from D-Ala-D-Ala to D-Ala-D-Lac, which has a
reduced affinity for vancomycin.
7. Horizontal Gene Transfer (HGT)
The rapid spread of antibiotic resistance is often facilitated by
horizontal gene transfer, which allows bacteria to acquire
resistance genes from other organisms.
Conjugation:

o Transfer of plasmids carrying resistance genes through

direct cell-to-cell contact. For example, conjugative
plasmids like the F plasmid in E. coli can carry
multiple resistance genes.
Transformation:

o Uptake of free DNA from the environment, including

fragments carrying resistance genes.
Transduction:

o Bacteriophages can inadvertently package and transfer
 bacterial DNA containing resistance genes during the
lytic or lysogenic cycle.
8. Mobile Genetic Elements
Plasmids:

o Circular DNA molecules that replicate independently

of the bacterial chromosome. They often carry
multiple resistance genes and can be transferred
between bacteria via conjugation.
Transposons and Insertion Sequences:

o Transposons (e.g., Tn3) can move resistance genes

between DNA molecules, including plasmids and
chromosomes.
o Integrons: Genetic elements that can capture and

express genes, particularly resistance genes, through
site-specific recombination mediated by an integrase
enzyme.
Pathogenicity Islands and Genomic Islands:

o Large DNA segments acquired through horizontal gene

transfer that often carry clusters of resistance genes.
These islands are typically integrated into the bacterial
chromosome and may be associated with virulence
factors.
9. Mutation and Adaptive Evolution
Spontaneous Mutations:

o Random mutations in bacterial genomes can lead to

resistance. For instance, mutations in the rpoB gene
confer resistance to rifampin by altering the binding
site on RNA polymerase.
Adaptive Evolution:

o Under selective pressure, such as antibiotic exposure,

resistant bacteria are more likely to survive and
 propagate. Over time, this leads to the predominance
of resistant strains in a population.
Conclusion
Bacteria deploy a wide array of genetic mechanisms to
counteract antimicrobial agents, including enzymatic
degradation, target modification, efflux pump activity, reduced
permeability, biofilm formation, and horizontal gene transfer.
These mechanisms allow bacteria to survive and thrive in the
presence of antibiotics, contributing to the global challenge of
antimicrobial resistance (AMR). Understanding these
mechanisms is crucial for developing new strategies to combat
bacterial infections and curb the spread of resistance.
Infection & Immunity
BBS3024

Academic year: 2024–2024

Basic Challenge 3

Evolution of viruses

Faculty of Health, Medicine and Life Sciences
Bachelor Biomedical Science

 2017 Maastricht University, Faculty of He alth, Medicine and Life Sciences.
Nothing in this publication may be reproduced and/or made public by means of printing, offset, photocopy or microfilm
or in any digital, electronic, optical or any other form without the prior written permission of the owner of the
copyright.
 Faculty of Health, Medicine and Life Sciences

The Trick.
"Any virus that can cause disease in humans must have at least one immune evasion mechanism—at least one
immune evasion “trick.” Without the ability to evade the immune system, a virus is usually harmless. Understanding
immune evasion by a virus is frequently important for understanding the pathogenesis of the virus, as well as
understanding challenges faced by the adap ve immune system and any candidate vaccine."
Literature:
Se e A, Cro y S. Adap ve immunity to SARS-CoV-2 and COVID-19. Cell. 2021;184(4):861-880. doi:10.1016/j.cell.2021.01.007

Case COVID 19.

A 48-year-old man presents to the emergency department, referred by his family doctor due to fever and significant
shortness of breath. He has experienced flu-like symptoms for the past three days—fever, muscle aches, sore throat,
runny nose, and cough—coupled with progres-sive shortness of breath that has not responded to oral an bio cs
(amoxicillin). Notably, he reports a recent loss of smell and taste.
The pa ent's medical history reveals obesity (body mass index: 31 kg/m²) and a long history of smoking—one pack of
cigare es per day for 25 years, along with vaping for the last three years. He has not received vaccina ons for
influenza A and B or for SARS-CoV-2. In his community, several individuals are exhibi ng similar flu-like symptoms.
On physical examina on, he has fever and exhibits signs of dyspnea and tachypnea, with a rapid pulse and normal
blood pressure. Ausculta on reveals bilateral lung involvement con-sistent with pneumonia. He requires
supplemental oxygen at 5 liters per minute via nasal can-nula to maintain acceptable oxygen satura on levels.
A nasopharyngeal swab tests posi ve for SARS-CoV-2 via polymerase chain reac on (PCR), with a cycle threshold (CT)
value of 22, while tests for influenza and parainfluenza viruses are nega ve. Laboratory results indicate signs of
systemic inflamma on. Imaging studies, includ-ing chest X-ray and CT scan, reveal diffuse bilateral pneumoni s
without lung emboli.
The medical team diagnoses him with severe COVID-19 pneumonia. They ini ate treatment with intravenous
dexamethasone and tocilizumab to manage the inflammatory response. Ad-di onally, they deliberate on further
therapeu c op ons, including remdesivir, nirma-trelvir/ritonavir, molnupiravir, monoclonal an bodies, or
convalescent plasma. They also plan to assess his blood serum for the presence of an bodies against SARS-CoV-2,
which may in-form his immune status.

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BBS3024 2022-2023 2
 Faculty of Health, Medicine and Life Sciences

Case HIV
A 32-year-old woman is referred by her family doctor to the emergency department because of high fever, flu-like
symptoms, cervical lymphadeni s, and a skin rash. Her previous medical history is unremarkable. On physical
examina on she appears ill. Temperature 39.0⁰ Celsius, blood pressure 120/80 mmHg and pulse rate 94/minute. Her
tonsils are enlarged. Cervical, axillary and inguinal lymph nodes are enlarged and elas c on palpa on. Blood results
show lymphocytopenia. Serology is posi ve for an acute HIV (human immunodeficiency virus) infec on, Fiebig stage
3. The consulted infec ous diseases specialist recommends the pa ent to start combina on an retroviral therapy
(cART) immediately. However, the pa ent is in doubt and wonders why she can’t wait to see how the infec on
evolves and if her immune system can cure the infec on. Next to this, she wants to know if HIV, like covid-19, also has
a lot of variants.

Compare and constrast: SARS-CoV2 and HIV

BBS3024 Infection & Immunity 2024-2025 3

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1. Types of viruses recap
1. Based on Genetic Material:
Viruses are distinguished by whether their genome consists of
DNA or RNA, and whether this genetic material is single or
double-stranded.
DNA Viruses:

o Double-Stranded DNA (dsDNA) Viruses: These

viruses have double-stranded DNA similar to human
DNA, which allows them to use the host's cellular
machinery efficiently.
▪ Examples:

▪ Herpesviruses (e.g., HSV-1 and HSV-2)

cause cold sores and genital herpes. They
can remain latent and reactivate under
certain conditions.
▪ Adenoviruses cause respiratory infections

and conjunctivitis.
▪ Poxviruses (e.g., Variola virus) cause

smallpox. They are unique because they
replicate in the cytoplasm rather than the
nucleus.
o Single-Stranded DNA (ssDNA) Viruses: These

viruses contain only one strand of DNA and often
require the host cell to synthesize a complementary
strand.
▪ Examples:

▪ Parvoviruses (e.g., B19 virus) cause

conditions like Fifth disease in children and
 can infect animals too.
▪ Circoviruses cause diseases in pigs and birds

and are circular ssDNA viruses.
RNA Viruses:

o Positive-Sense Single-Stranded RNA (ssRNA+)

Viruses: The viral RNA can act directly as messenger
RNA (mRNA), allowing for immediate protein
synthesis upon infection.
▪ Examples:

▪ Picornaviruses (e.g., Poliovirus, Rhinovirus)

cause diseases like polio and the common
cold.
▪ Coronaviruses (e.g., SARS-CoV-2) cause

respiratory diseases, including COVID-19,
and have a distinctive spike protein for cell
entry.
▪ Flaviviruses (e.g., Dengue, West Nile Virus)

are primarily mosquito-borne and cause
serious diseases.
o Negative-Sense Single-Stranded RNA (ssRNA-)

Viruses: The viral RNA is complementary to mRNA
and must be transcribed into a positive-sense RNA by
RNA-dependent RNA polymerase before translation.
▪ Examples:

▪ Orthomyxoviruses (e.g., Influenza virus)

cause flu. They have segmented genomes,
leading to rapid antigenic shifts.
▪ Filoviruses (e.g., Ebola virus) cause

hemorrhagic fever with high mortality rates.
▪ Rhabdoviruses (e.g., Rabies virus) have a

bullet shape and affect the nervous system.
 o Double-Stranded RNA (dsRNA) Viruses: These
viruses have double-stranded RNA and replicate
within a protective capsid to evade the host's immune
response.
▪ Examples:

▪ Reoviruses (e.g., Rotavirus) cause

gastroenteritis, especially in children.
Retroviruses (RNA viruses with reverse transcription):

Retroviruses contain ssRNA, which is reverse-transcribed
into DNA, allowing them to integrate into the host genome.
o Examples:

▪ HIV (Human Immunodeficiency Virus) causes

AIDS by integrating into host T-cells and slowly
weakening the immune system.
▪ HTLV (Human T-cell Leukemia Virus) can

cause adult T-cell leukemia/lymphoma.

2. Based on Replication Strategy (Baltimore Classification):
This system groups viruses into seven classes based on how they
produce mRNA, which is essential for protein synthesis.
Class I: Double-Stranded DNA Viruses

o Examples: Herpesviruses and Adenoviruses.

Class II: Single-Stranded DNA Viruses

o Examples: Parvoviruses.

Class III: Double-Stranded RNA Viruses

o Examples: Reoviruses (like Rotavirus).

Class IV: Positive-Sense Single-Stranded RNA Viruses

o Examples: Flaviviruses (e.g., Dengue), Coronaviruses

(e.g., SARS-CoV-2).
Class V: Negative-Sense Single-Stranded RNA Viruses
 oExamples: Influenza, Rabies virus.
Class VI: Positive-Sense Single-Stranded RNA Viruses with

Reverse Transcriptase
o Examples: HIV (retroviruses).

Class VII: Double-Stranded DNA Viruses with Reverse

Transcriptase
o Examples: Hepatitis B Virus (HBV).

3. Based on Shape and Structure:
The physical shape and structure of viruses influence how they
interact with host cells.
Helical Viruses: These viruses have rod-like or filamentous

shapes where the capsid proteins wind around the genome.
o Examples:

▪ Tobacco Mosaic Virus infects plants and has a

rigid, rod-shaped structure.
▪ Rabies Virus has a bullet shape and infects nerve

cells.
Icosahedral Viruses: These are roughly spherical and have a

capsid made of 20 triangular faces, forming an icosahedron.
o Examples:

▪ Adenovirus causes respiratory diseases and

conjunctivitis.
▪ Poliovirus affects the nervous system and can lead

to paralysis.
Complex Viruses: These have more intricate structures,

often with additional features like protein tails.
o Examples:

▪ Bacteriophages have a head-tail structure, where

the head contains the genetic material, and the
 tail helps infect bacteria.
▪ Poxviruses have complex, multilayered outer walls

and cause diseases like smallpox.

4. Based on Host Range:
Viruses can also be classified by the type of host they infect.
Animal Viruses: Infect various animal species, including

humans. They can be DNA or RNA viruses and cause a
range of diseases.
o Examples: Influenza (affects many mammals), Rabies

(affects mammals), and HIV (human-specific).
Plant Viruses: These viruses specifically infect plants and

are often transmitted by insect vectors.
o Examples:

▪ Tobacco Mosaic Virus affects tobacco plants and

other plants in the Solanaceae family.
▪ Potato Virus Y causes serious diseases in potato

crops.
Bacteriophages: Also known as phages, these viruses infect

bacteria. They are commonly used in research and can be
potential therapeutic tools.
o Examples:

▪ T4 Bacteriophage infects E. coli and has a

complex structure with a head-tail arrangement.
▪ Lambda Phage also infects E. coli and integrates

its genome into the bacterial DNA.
Archaea Viruses: Infect archaea, which are microorganisms

distinct from bacteria.
o Examples: The Sulfolobus turreted icosahedral

virus (STIV) infects archaea in high-temperature
 environments.

5. Based on Mode of Transmission:
Airborne Viruses: Spread through respiratory droplets or
aerosols.
o Examples: Influenza virus, SARS-CoV-2, and Measles

virus.
Vector-Borne Viruses: Transmitted by insects or other

vectors.
o Examples: Dengue (spread by mosquitoes), West Nile

Virus, and Zika virus.
Food and Water-Borne Viruses: Transmitted via

contaminated food or water.
o Examples: Norovirus (common cause of

gastroenteritis), Hepatitis A virus.
Blood-Borne Viruses: Spread through blood and bodily

fluids.
o Examples: HIV, Hepatitis B, and Hepatitis C.

Zoonotic Viruses: Transmitted from animals to humans,

often resulting from close contact with animal hosts.
o Examples: Ebola (from fruit bats or other wildlife),

Rabies (from infected animals), and certain strains of
Influenza.
General Virology (Recap)
1. Viral Genome: Viral genomes vary in structure and are a
primary basis for virus classification. They may consist of
either DNA or RNA, which can be single-stranded (ss) or
double-stranded (ds):
o DNA Viruses include both double-stranded (dsDNA)

and single-stranded (ssDNA) forms. For
instance, Herpesviruses (dsDNA) have genomes that
 can integrate with host mechanisms and establish
latency. Adenoviruses (dsDNA) cause respiratory
illnesses, while Parvoviruses (ssDNA) can infect
animals and humans, causing diseases like Fifth
disease.
o RNA Viruses include positive-sense ssRNA, negative-

sense ssRNA, and dsRNA viruses. Positive-sense
ssRNA viruses (e.g., SARS-CoV-2) can translate
directly into proteins. Negative-sense ssRNA viruses
(e.g., Influenza) require transcription to a positive
strand before translation. Retroviruses like HIV,
unique among RNA viruses, reverse-transcribe RNA
into DNA, allowing integration into the host genome.
2. Viral Morphology: Viruses have distinct shapes that play a
role in their interactions with host cells:
o Helical Viruses: These have a rod-like structure where

the viral genome is coiled within a capsid cylinder, as
seen in the Tobacco Mosaic Virus and Rabies virus.
o Icosahedral Viruses: These have a spherical

appearance due to their 20-sided capsid structure.
Examples include Poliovirus and Adenovirus, known
for their stability.
o Complex Viruses: This category includes more

complex shapes and additional structural components,
such as the head-tail structure of bacteriophages and
the multilayered structure of Poxviruses.
3. Enveloped vs. Naked Capsid Viruses:
o Enveloped Viruses have a lipid membrane

surrounding their capsid, derived from the host cell,
which contains embedded viral proteins. This
envelope is essential for binding to host receptors.
Enveloped viruses include HIV and SARS-CoV-2.
 o Naked Capsid Viruses lack this lipid envelope and
consist of only a protein capsid protecting the genome,
making them more resilient in external environments
(e.g., Poliovirus and Adenovirus).
4. Viral Attachment Proteins: Viral attac