Lecture 6 Human Pathogen note.docx

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**Lecture 6 Human Pathogen Part 3**

Three different types of bacteria:

Primary pathogens (capable of causing disease) -- Salmonella, Shigella,
Yersinia, Klebsiella pneumoniae, Escherichia coli -- Most of the species
within the genus are considered pathogens, for some it's just 1 or 2.

Opportunistic Pathogens -- under particular conditions

Non-pathogenic

General characteristics

- Gram -ve rods with no specific arrangement

- Non-spore forming

- Aerobic and facultative anaerobic

- Motile by peritrichous flagella or non-motile

- Capsulated with ill-defined slime later or non-capsulated

- Fimbriae or pili present is most species

- Lactose fermenter

- Catalase +ve

- Reduce nitrate to nitrite

- Grow on peptone or meat extract media without the addition of sodium
chloride or other supplements.

**Antigenic structure**

O antigens -- in the polysaccharide of cell wall (LPS)

H antigens -- flagellar protein

Type 1 pilli -- the most common one

CFA, BFP, P- pili

K antigen -- polysaccharide capsule (only for some species) Not all have
capsules

Vi antigen -- virulence

- Salmonella species only

O, H, K -- the most common ones

**Escherichia coli**

\>150 serotypes

All typed by O and H

Example: O157:H7 (EHEC)

**Shigella** -- just looking at O for Serogroups

4 different species -- S. dysenteriae, S.flexneri, S. boydi, S. sonnei

Each have different serogroups: A -- 10 types, B -- 6 types, C -- 15
types, D -- just 1.

Salmonella

\>2000 serotypes

Typhoidal vs non-typhoidal are the main ones to distinguish between

\+ Yersinia

- Pseudotuberculosis -- cause diseases similar to tuberculosis

- Enteracalitica -- diarrheal disease

**Epidemiology of Enterobacteriaceae**

Molecular pathogenesis of Enterobacteriaceae

Fecal-oral spread -- contaminated food goes into a person (Salmonella
with typhi serotype & Shigella) or from an animal (Salmonella & E.coli)
can come into a person

Through Gastrointestinal tract

Once it gets into the colon (generally) =\> different types of problems
=\> get into the bloodstream (UTI), urinary tract, fever.

Stays in the colon =\> causing diarrhea

***Escherichia***

- *E.albertii*

- *E.coli*

- *E.fergusonii*

- *E. hermannii*

- *E. vulneris*


***Escherichia coli***

- Gram -ve bacilli

- Motile; facultative anaerobe Grow in both aerobic and anaerobic

- \ this is how they cause
diseases.

**Transmission:**

Fecal-oral transmission in general -- contaminated stools =\> into
water, food, unwashed hands =\> into the person orally =\> gets to
intestines and stomach =\> cause illness

It has to get out the lumen and into the cells in order to cause the
symptoms. Shiga toxin +ve symptoms: bloody stools/diarrhea and fever,
causing the bad excretion of the pathogen to come back out and restart
the transmission cycle.


This is proteobacteria but not Enterobacteriaceae -- the symptoms that
it causes are very similar to Enterobacteriaceae.

Campylobacter jejuni -- jejunum is a part of the GI tract -- where the
name comes from

***Campylobacter spp.***

- Gram -ve

- Slender, curved, Long spiral-shaped rods, maybe coccoid in really
old culture (a bit more round)

- Motile (single polar unsheathed flagellum at one or both ends)

- Non-spore former

- Microaerophilic & capnophilic Different to Enterobacteriaceae

- Have to grow them at reduced oxygen and increased CO~2~

- Fastidious

- Temperature -- grows at 42°C -- adapted to chickens with higher body
temp.

- Unable to use sugars either oxidatively or fermentatively; derive
energy from amino acids; Not grow on MAC or NA; Should grow them on
chocolate agar.

- Virulence factors

- Motility Allow them to burrow(dig) down through the mucus layer

- Heat-labile enterotoxin = heat sensitive

**Transmission:**

Intestinal colonisation in Chicken -- does not cause any problems to
chickens.

Not cooked enough, contaminated =\> eat =\> infection

OR

Contamination of faeces from chickens =\> water, other animals,
particularly into milk =\> unpasteurised milk that's contaminated with
campylobacter

**\
**

***Campylobacter spp.***

Comma-shaped (curved)

\- **Common Cause**: One of the most common causes of bacterial
gastroenteritis worldwide.

\- **Common Sources**: Found in foods like poultry and unpasteurised
milk.

**Anatomy and Physiology:**

\- Cell Wall: Thin peptidoglycan cell wall; appears pink/red when
gram-stained (gram-**negative** bacteria).

\- Motility: Has a flagellum at one end, making it motile.

\- Oxidase Test: Oxidase positive (can use oxygen to create ATP).

\- Growth Conditions:

\- Microaerophile (thrives in low oxygen environments).

\- Optimal temperature: 42°C.

\- Grows on blood agar varieties like Skirrow, butzler, and Campy-BAP.
Chocolate agar (fastidious)

**Transmission:**

\- Route: Fecal-oral transmission.

\- Common Carriers:

\- Birds (particularly in the gastrointestinal tract of poultry).

\- Cows (risk from unpasteurised milk).

\- Infected pets (notably puppies).

**Pathogenesis and Virulence Factors:**

\- Attachment: Uses fimbri-like filaments and cell surface proteins like
PEV-1 and CADF to attach to the mucosa of the small intestine and colon.

\- Invasion:

\- Drills into mucosa using its spiral shape and long flagella.

\- Releases cytotoxins like cytolethal distending toxins (CDT), causing
cell damage and inflammation.

\- Complications:

\- Toxic Megacolon: Extensive inflammation can lead to colon dilation.

\- Bacteremia: Bacteria can enter the bloodstream.

\- Guillain-Barré Syndrome: The immune system produces antibodies that
attack peripheral nerves, causing paralysis.

\- Reactive Arthritis: Autoimmune reaction causing joint inflammation.

**Symptoms:**

\- Incubation Period: 1-7 days.

\- Initial Symptoms: Fever, muscle pain, malaise, headache.

\- Gastrointestinal Symptoms:

\- Crampy abdominal pain.

\- Watery diarrhea initially, which may turn bloody.

\- Bloody diarrhea is more common in children.

\- Complication Symptoms:

\- Toxic Megacolon: Bloating, tachycardia, loss of bowel sounds.

\- Guillain-Barré Syndrome: Ascending paralysis (starting at the feet
and moving upwards).

\- Reactive Arthritis: Pain in large joints.

**Diagnosis:**

\- Clinical Manifestations: Based on symptoms.

\- Stool Sample Examination:

\- Gram-negative, comma-shaped bacteria.

\- Presence of white and red blood cells.

\- Cultures: Isolating the bacteria on specific media.

**Treatment:**

\- General Treatment: Hydration and correcting electrolyte imbalances.

\- Severe Infection: Antibiotics like erythromycin.

**Distinguishing from Other Bacteria:**

\- Gram Staining: Both Campylobacter and Enterobacteriaceae are
gram-negative.

\- Microscopy: Campylobacter is comma-shaped, while Enterobacteriaceae
are rod-shaped.

\- Motility: Campylobacter is motile (distinguishing it from non-motile
Shigella).

\- Incubation Conditions:

\- Campylobacter grows in low oxygen and warmer temperatures.

\- Enterobacteriaceae do not have such specific growth requirements.

\- Growth Requirements:

\- Campylobacter requires specialised media (e.g., chocolate agar).

\- Enterobacteriaceae grow on a wider range of media.

\- Oxidase Test:

\- Campylobacter is oxidase positive.

\- Enterobacteriaceae are oxidase negative.

***Shigella* spp*.***

**General Information:**

\- Family: Enterobacteriaceae

\- Species:

\- Shigella dysenteriae

\- Shigella flexneri

\- Shigella boydii

\- Shigella sonnei

\- All species can cause **shigellosis**, a contagious intestinal
infection, which can progress to dysentery.

**Anatomy and Physiology:**

\- Gram-negative (appears red or pink).

\- Rod-shaped.

\- Facultative anaerobe (can survive with or without oxygen).

\- Motility: Non-motile (lacks flagella).

\- Non-spore former

\- Non-lactose fermenter.

\- Urease and oxidase negative.

\- H~2~S negative

**Identification:**

\- Culture Medium: Grows on selective media like MacConkey agar.

\- Forms white, non-lactose fermenting, non-hydrogen sulfide-producing
colonies.

\- Microscopy: Stool stains with methylene blue may show
polymorphonuclear leukocytes.

\- PCR Testing: Direct identification of Shigella DNA.

**Pathogenesis:**

1\. Ingestion and Initial Infection:

\- Shigella is ingested and multiplies in the small intestine before
passing into the colon.

\- Targets epithelial cells of the mucosal lining, particularly M-cells.

2\. Invasion and Immune Response:

\- M-cells phagocytose Shigella and release it into mucosa-associated
lymphoid tissues (MALT).

\- Macrophages in MALT gobble up Shigella, but Shigella induces
apoptosis in macrophages.

\- Release of cytokines (e.g., interleukin-1-beta) triggers intense
inflammation, attracting more immune cells, damaging epithelial cells,
and causing ulcerations and abscesses.

3\. Spread within the Host:

\- Disrupts cellular junctions, allowing Shigella to enter enterocytes.

\- Uses type III secretory system to inject proteins into enterocytes,
inducing phagocytosis.

\- Inside enterocytes, Shigella escapes the phagosome into the
cytoplasm, uses actin-based motility to move and spread infection.

4\. Shiga Toxin (specific to Shigella dysenteriae serotype 1):

\- An AB toxin (two subunits: A and B).

\- B subunit binds to the host cell membrane; toxin engulfed into the
phagosome.

\- Acidic environment in phagosome breaks disulfide bond, separating
subunits.

\- A subunit diffuses into the cytoplasm, and cleaves 28S rRNA in
ribosomes, halting protein synthesis and causing cell death.

\- Can reach the bloodstream and cause hemolytic uremic syndrome (HUS).

**Symptoms:**

\- Symptoms last about seven days.

\- infected person can be a carrier for infection up to 4 weeks after
the onset of symptoms.

\- Typical Symptoms:

\- Severe abdominal and rectal cramping and pain.

\- High fever, vomiting, loss of appetite.

\- Watery, mucus-like diarrhea, potentially containing **blood** or pus.
Bloody diarrhea

\- Complications:

\- Hemolytic Uremic Syndrome (HUS): Hemolytic anemia, kidney failure,
thrombocytopenia.

\- Tonic-Clonic Seizures: Particularly in children.

\- Sepsis: Mostly in neonates, malnourished children, and people with S.
dysenteriae serotype 1 infection.

\- Reactive Arthritis: Pain and swelling in knee joints.

**Transmission:**

\- Fecal-oral transmission.

\- Sources:

\- Contaminated water or food.

\- Flies carrying stool particles.

\- Contact with contaminated objects or hands.

\- Sexual contact (occasionally).

**- Virulence: Extremely virulent; as few as 10 bacteria can cause an
infection.**

**- Survival: Can survive the acidic environment of the stomach.**

**Diagnosis:**

\- Fecal Sample: Cultured on selective media like MacConkey agar.

\- Stool Stains: Methylene blue may show polymorphonuclear leukocytes.

\- PCR Testing: For direct identification of Shigella DNA.

**Treatment:**

\- General Treatment: Fluid and electrolyte replenishment.

\- Antibiotics: Beta-lactams (penicillins and cephalosporins),
macrolides, quinolones.

***Salmonella typhoidal (Salmonella typhi)***

**General Information**

\- Family: Enterobacteriaceae

\- Species: Salmonella bongori and Salmonella enterica (with 6
subspecies)

\- Encapsulated gram-negative rod bacteria (appear red or pink on gram
stain)

\- Characteristics:

\- Facultative intracellular pathogens

\- Motile with flagella

\- Non-spore former

\- Facultative anaerobes (can undergo respiratory and fermentative
metabolism)

\- Can ferment glucose but not lactose

\- Oxidase negative

\- H~2~S positive

\- Specific to Humans: Only infects humans and causes enteric fever
(typhoid fever)

**Pathogenesis**

\- Ingestion and Targeting:

\- Reaches distal ileum of the small intestine

\- Targets epithelial layer of the mucosal lining

\- Adheres to and is phagocytosed by M cells

\- Spit into underlying Peyer\'s patches

\- Immune Evasion:

\- Vi capsular polysaccharide antigen protects against antibody tagging

\- Suppresses neutrophil recruitment

\- Induces recruitment of monocytes and macrophages

\- Can cause hypertrophy, necrosis, and potentially ileal perforation

\- Survival and Replication:

\- Phagocytosed by macrophages, forming a salmonella-containing vacuole

\- Type III secretion system injects effector proteins, preventing
vacuole-lysosome fusion

\- Survives and replicates within the vacuole

**- Systemic Spread:**

\- Uses macrophages to enter lymphatic vessels and systemic lymphatic
circulation

\- Reaches reticuloendothelial tissues (liver, spleen, bone marrow,
gallbladder)

\- Induces macrophage apoptosis, causing bacteremia

\- Can lead to sepsis

**- Complications:**

\- Osteomyelitis in individuals with spleen issues

\- Chronic infection and carrier state (gallbladder reservoir)

**Transmission**

\- Routes: Fecal-oral, poor sanitation, poor hygiene, contaminated
water/food, particularly endemic to Asia, Africa, Latin America, and the
Caribbean

\- Inoculum: Requires about 100,000 microorganisms to cause infection

**Symptoms**

\- Onset: 1-2 weeks after infection

\- Duration: 4-6 weeks

\- Typical Symptoms:

\- High sustained fever

\- Abdominal pain

\- Constipation followed by diarrhea

\- Rose or salmon-coloured spots on chest and abdomen

\- Hepatomegaly and splenomegaly

\- Dehydration, weakness, headaches, and cloudy mental state in advanced
cases

**Diagnosis**

\- Methods: Blood culture, stool culture, intestinal secretions (vomit
or duodenal aspirate), and gallbladder bile culture for carriers

**Treatment**

\- Symptomatic Management: Fluid and electrolyte replenishment, NSAIDs
for pain and fever

\- Antibiotics: Broad-spectrum antibiotics like fluoroquinolones or
cephalosporins (ceftriaxone)

\- Carriers: Combination of antibiotics and gallbladder removal

**Prevention**

\- Vaccines: Oral live attenuated vaccine and intramuscular vaccine
containing VI capsular polysaccharide

\- Hygiene: Proper sanitation and hygiene practices

***Non-typhoidal Salmonella***

**General Characteristics**

\- Serotypes: Over 2,500 serotypes within subspecies enterica

\- Common Serotype: Salmonella enteritidis

**Pathogenesis**

\- Ingestion and Targeting:

\- Reaches the distal ileum of the small intestine

\- Targets epithelial layer of the mucosal lining

\- Adheres to and is phagocytosed by M cells

\- Spit into underlying Peyer\'s patches

\- Immune Response:

\- Strong pro-inflammatory cytokine response

\- Recruitment of immune cells (especially neutrophils)

\- Causes enterocolitis (inflammation of the small intestine and colon)

\- Can lead to mucosal damage and ulcers

\- Potential Spread:

\- Usually limited to the mucosa and destroyed by local immune cells

\- In some cases, can become invasive and cause bacteremia

**Transmission**

\- Reservoirs: Infected humans and animals (birds, reptiles, mammals,
amphibians)

\- Routes: Fecal-oral, foodborne (contaminated raw/undercooked animal
products, water, fruits, vegetables, peanut butter), direct contact with
infected animals

**Symptoms**

\- Onset: 24-48 hours after infection

\- Typical Symptoms:

\- Watery diarrhea (sometimes bloody)

\- Abdominal cramps

\- Nausea and vomiting

\- Headache, chills, low-grade fever

\- Dehydration

**Diagnosis**

\- Methods: Stool culture on selective media, additional cultures for
invasive infections

**Treatment**

\- Symptomatic Management: Fluid and electrolyte replenishment,
suppressing nausea, alleviating pain

\- Antibiotics: Typically not indicated for uncomplicated infections;
used for invasive infections based on sensitivity of the strain

***Escherichia coli***

**Characteristics:**

\- Gram-negative: Thin peptidoglycan layer, stains pink with safranin
dye.

\- Rod-shaped bacteria.

\- Catalase-positive: Produces catalase enzyme.

\- Lactose fermenter: Produces beta-galactosidase and cleaves lactose
into glucose and galactose.

**Tests and Cultivation**

\- Catalase Test: Adding hydrogen peroxide to a colony; the presence of
catalase results in foaming.

\- Lactose Fermentation Test: Cultivation on lactose-containing media
(e.g., phenol lactose), resulting in acid production and colour change
from red to yellow.

\- Eosin Methylene Blue (EMB) Agar: Grows into black colonies with a
greenish-black metallic sheen.

**Physical Properties**

\- Encapsulation: Covered by a polysaccharide layer called a capsule.

\- Motility: Has flagella for movement.

\- Facultative Anaerobe: Can live with or without oxygen.

**Pathogenic Strains**

\- Attachment: Uses fimbriae to attach to host cells.

\- Serotype Classification: Based on antigens:

\- Somatic (O) antigens: On the cell membrane.

\- Capsular (K) antigens: On the capsule.

\- Fimbrial (F) antigens: On the fimbriae.

\- Flagellar (H) antigens: On the flagella.

**Serotypes and Diseases**

\- Examples:

\- K1 antigen: Causes neonatal meningitis.

\- O157:H7: Associated with hemorrhagic colitis, hemolytic uremic
syndrome, and diarrheal outbreaks.

\- Numerous Serotypes: Up to 200 serotypes.

**Pathotype Classification**

\- Pathotypes: Based on the disease-causing mechanism and virulence
factors:

1\. Shiga-like toxin-producing E. coli (STEC)

\- Produces Shiga toxin, causes bloody diarrhea, and can lead to
hemolytic uremic syndrome (HUS).

2\. Enterotoxigenic E. coli (ETEC)

\- Produces heat-labile and heat-stable enterotoxins, causing watery
diarrhea.

3\. Enteroinvasive E. coli (EIEC)

\- Invades and destroys intestinal epithelial cells, causing bloody
diarrhea.

4\. Enteropathogenic E. coli (EPEC)

\- Causes disease in children under two years old, leading to watery
diarrhea.

5\. Uropathogenic E. coli (UPEC)

\- Causes urinary tract infections (UTIs), including cystitis and
pyelonephritis.

**Pathogenesis of Each Pathotype**

**1. Shiga-like Toxin-Producing E. coli (STEC)**

- **Attachment**: STEC attaches to the host\'s intestinal cells using
fimbriae.

- **Toxin Production**: Produces Shiga-like toxins (Stx1 and Stx2).

- **Intestinal Injury**: Toxins cause damage to the intestinal
epithelium and blood vessels, resulting in inflammation.

- **Bloody Diarrhea**: Inflammation and vessel damage lead to
fluid and blood leaking into the intestinal lumen.

- **Hemolytic Uremic Syndrome (HUS)**:

- **Systemic Toxin Release**: Toxins enter the bloodstream,
affecting the kidneys.

- **Kidney Damage**: Toxins bind to endothelial cells in the
glomeruli, causing apoptosis and gaps in the capillary walls,
leading to proteinuria.

- **Inflammatory Response**: Cytokines and chemokines are
released, activating platelets and causing clot formation.

- **Thrombocytopenia**: Decreased platelet count due to clot
formation.

- **Hemolytic Anemia**: Red blood cells are fragmented
(schistocytes) as they pass through obstructed microvessels.

- **Ischemic Kidney Damage**: Clots obstruct arterioles, leading
to kidney ischemia, reduced filtration, and uremia.

**2. Enterotoxigenic E. coli (ETEC)**

- **Attachment**: ETEC uses fimbriae to adhere to the intestinal
mucosa.

- **Toxin Production**:

- **Heat-labile Enterotoxin (LT)**:

- **Mechanism**: Activates adenylate cyclase, increasing cAMP,
leading to chloride and water secretion.

- **Heat-stable Enterotoxin (ST)**:

- **Mechanism**: Activates guanylate cyclase, increasing cGMP,
leading to electrolyte and water secretion.

- **Outcome**: Causes watery diarrhea without damaging the intestinal
wall.

**3. Enteroinvasive E. coli (EIEC)**

- **Attachment and Invasion**: EIEC attaches to and invades intestinal
epithelial cells.

- **Intracellular Multiplication**:

- **Invasion**: Invades and multiplies within epithelial cells,
causing cell destruction.

- **Inflammatory Response**: Triggers a strong inflammatory response,
leading to widespread epithelial damage and bloody diarrhea.

**4. Enteropathogenic E. coli (EPEC)**

- **Attachment**: EPEC uses bundle-forming pili (BFP) to attach to
intestinal epithelial cells.

- **Effacement**:

- **Mechanism**: Injects effector proteins via a Type III
secretion system, causing actin cytoskeleton rearrangement.

- **Effect**: Leads to pedestal formation and microvilli
effacement.

- **Outcome**: Impairs absorption, causing watery diarrhea, primarily
in children under two years of age.

**5. Uropathogenic E. coli (UPEC)**

- **Colonization**: UPEC can colonize the periurethral area and ascend
the urinary tract.

- **Adhesion and Invasion**:

- **Fimbriae**: Uses type 1 fimbriae and P fimbriae to adhere to
uroepithelial cells.

- **Invasion**: Invades and replicates within bladder cells.

- **Toxin Production**:

- **Hemolysins**: Produces alpha and beta hemolysins, causing
lysis of urinary tract cells.

- **Ascending Infection**:

- **Cystitis**: Infection of the bladder, causing dysuria and
frequent urination.

- **Pyelonephritis**: Can ascend to the kidneys, causing flank
pain and more severe symptoms.

**Symptoms and Complications**

\- General Symptoms: Diarrhea, abdominal cramps, vomiting.

\- STEC: Bloody diarrhea, low-grade fever, potential HUS with symptoms
like body swelling, confusion, and jaundice.

\- ETEC: Watery diarrhea, possible fever, and bloating.

\- EIEC: Bloody diarrhea and chills.

\- EPEC: Severe dehydration in children, prolonged diarrhea leading to
malnutrition.

\- UPEC: UTI symptoms like dysuria, urinary frequency, and possible
flank pain if kidneys are affected.

**Diagnosis**

\- General Diagnosis:

\- Gram Staining: On stool or urine sample.

\- Culture: On eosin methylene blue agar.

\- HUS Diagnosis: Identifying Shiga toxin in the blood.

**Treatment**

\- Diarrhea:

\- Hydration and rest.

\- Antibiotics in severe cases (e.g., doxycycline, cotrimoxazole).

\- Hemolytic Uremic Syndrome (HUS):

\- Supportive care: Dialysis, corticosteroids, blood transfusions,
plasmapheresis.

\- UTIs:

\- Antibiotics: Cotrimoxazole, nitrofurantoin, fluoroquinolones (e.g.,
ciprofloxacin).