Bacterial Infections Of The GIT PDF

Summary

This presentation details bacterial infections of the gastrointestinal tract (GIT), covering their overview, epidemiology, and clinical features. Different types of bacterial infections, including various E. coli strains, Shigella species, Campylobacter species, Vibrio cholerae, Yersinia enterocolitica, Helicobacter pylori, and Mycobacterium tuberculosis, are discussed. The presentation also includes information about normal flora, pathogenesis, and laboratory diagnosis of these infections.

Full Transcript

Bacterial Infections of the
Gastrointestinal tract(GIT)

Dr S. Haffejee
Dept. of Medical
Microbiology
 Overview
Normal flora of the GIT
Pathogenic bacteria causing disease of the GIT
- Diarrhoeagenic E. Coli
- Shigella species
- Campylobacter species
- Vibrio cholerae
- Yersinia enterocolitica
- Helicobacter pylori
- Mycobacterium tuberculosis
 Normal flora of the GIT
AGE BACTERIAL FLORA
Foetus Sterile
Birth Begins as sterile, then colonisation begins as
baby is fed and handled.
Breastfed infants Bifidobacteria(90%), Enterobacteriaceae,
Enterococcus species, Streptococci(viridans
group)
Bottle-fed infants Bifidobacteria not predominant,
Enterobacteriaceae, Enterococcus species,
Streptococci(viridans group), anaerobes
Children and Adults(according to anatomical Oral cavity, Oesaphagus: Streptococcus
site) viridans, anaerobes
Stomach: lactobacilli
Proximal small intestine: lactobacilli,
Enterococcus faecalis(105-107 bacteria/ml of
fluid)
Distal small intestine: 108/ml as for proximal
plus Enterobactericeae, and Bacteroides
Colon/large intestine: 1011 bacteria/ml ,
Enterobacteriaceae more prominent,
enterococcus, lactobacilli, Clostridium species,
Pathogenic bacteria causing GIT
infections
 Clinical features
The most prominent features are:
Fever, Vomiting, Abdominal pain
Diarrhoea : central feature
✔ Nature of diarrhoea forms the basis for the
classification of GIT infections into 3 major
syndromes
✔ 1)Watery diarrhoea; 2)Dysentery; 3)Enteric
fever
✔ Enteric fever will be discussed in a separate
lecture.
 Clinical features
Watery diarrhoea
Stools have a fluid character
Intestinal fluid loss is the main feature
Other symptoms: nausea, vomiting, abdominal pain,
fever. Lasts 1-3 days
Pathogenesis: the pathogen attacks the proximal small
intestine. This part of the bowel is responsible for
>90% of physiologic net fluid absorption.
Pathogens: Vibrio cholerae; Enterotoxigenic E.
Coli(ETEC)
 Clinical features
Dysentery
Loose stools with blood and pus
Fever, abdominal pain, cramps, tenesmus.
Symptoms last 2-7 days
Focus of pathology is the colon
Pathogenesis: bacteria produce inflammatory
and/or destructive changes in the colonic
mucosa either by direct invasion/cytotoxin
production
Pathogens: Shigella species
 Epidemiology
Infections are acquired by
ingestion/faecal-oral route
Infections occur worldwide, but more
prevalent in low socio-economic groups, with
poor nutrition, sanitation and unsafe water
supply.
Many of these infections will be self limiting.
In children, infants: diarrhoeal disease remains
one of the most important causes of morbidity
and mortality.
 Epidemiology
Travellers diarrhoea(“Delhi belly”)
± 20-50% of travellers from developed
countries going to less developed countries
may develop diarrhoea
Common causes: Enterotoxigenic E. Coli,
Shigella spp.
Ingestion of uncooked or incompletely cooked
foods most likely source of infection. Eg. Raw
vegetables/salads
 Epidemiology
Hospital-associated diarrhoea
Causative agents: E. Coli in infants(rare), Clostridium difficile
(patients on antibiotics)
C. difficile: Gram positive bacillus, anaerobe, toxin-producing,
spore forming
C. difficile may cause mild diarrhoea to fulminant
pseudomembranous colitis during or after treatment with
antibiotics
The toxins(A and B) produced by the organism are responsible for
disease.
May be resident in patient’s own intestinal flora or acquired by
spread from other patients in the hospital.
Antibiotics implicated include: broad spectrum penicillins,
cephalosporins, clindamycin
Lab diagnosis: Toxin detection by ELISA/PCR on stool sample
Treatment: stop antibiotics, replace fluid and electrolytes. Oral
metronidazole, oral vancomycin
 Micro-organisms
E. Coli: Enteroinvasive; Enterotoxigenic;
Enterohaemorrhagic; Enteropathogenic
Shigella species
Campylobacter species
Vibrio cholerae
Yersinia enterocolitica
Helicobacter pylori
Mycobacterium tuberculosis
 Escherichia coli
Diarrhoea-causing E. coli are conveniently
classified according to their virulence
properties as:
Enterotoxigenic (ETEC)
Enteropathogenic (EPEC)
Enteroinvasive (EIEC)
Enterohaemorrhagic (EHEC), or
Enteroaggregative (EAEC).
 E. coli -Microbiology
Belongs to family Enterobacteriaceae
Gram negative bacillus, lactose-fermenter, produces indole
Grows readily on simple media under aerobic and anaerobic
conditions eg. MacConkey agar
Components of the cell wall and surface, which are antigenic
include:
The outer membrane lipopolysaccharide (LPS) is called the O
antigen.
Cell surface polysaccharides may form a well-defined capsule or an
amorphous slime layer and are termed the K antigen(capsule).
Motile strains have protein peritrichous flagella, which extend well
beyond the cell wall and are called the H antigen.
O,H,K antigens are used to divide organism into serotypes eg. E.
Coli O157:H7
Possess virulence factors such as adherence pili, exotoxins, LPS
GRAM STAIN SHOWING GRAM NEGATIVE
BACILLI

E. coli -LACTOSE FERMENTERS on MacConkey agar
 Enterotoxigenic E. coli(ETEC)
Epidemiology
ETEC are the most important cause of traveller’s diarrhoea
in visitors to developing countries.
ETEC also produce diarrhoea in infants native to these
countries, where they are a leading cause of morbidity and
mortality during the first 2 years of life.
Repeated bouts of diarrhoea caused by ETEC and other
infectious agents are an important cause of growth
retardation, malnutrition, and developmental delay in the
third world countries where ETEC are endemic.
ETEC disease is rare in industrialized nations.
Transmission is by consumption of food and water
contaminated by human waste
The infecting dose is high. Causes watery diarrhoea.
Disease lasts few days
 Enterotoxigenic E. coli(ETEC)
Pathogenesis
ETEC strains produces 2 enterotoxins viz. labile toxin(LT)
and/or stable toxin(ST), in the small intestine.
Adherence to surface microvilli is mediated by the
Colonising factor antigen(CFA) class of pili and is essential
for the efficient delivery of toxin to the target enterocytes.
The genes encoding the ST, LT, and the CFA pili are borne in
plasmids.
The bacteria remain on the surface, where the adenylate
cyclase–stimulating action of the toxin(s) creates the flow of
water and electrolytes from the enterocyte into the
intestinal lumen.
There is no invasion or inflammation.
 Enterotoxigenic E. coli(ETEC)
Labile toxin=LT:
Similar to cholera toxin. Acts on the small intestine
Its subunit B attaches to the GMI ganglioside at the brush border of
the small intestinal mucosal epithelial cells and facilitates entry of
subunit A into the cell.
Subunit A activates adenyl cyclase and markedly increases cyclic
AMP which results in intense and prolonged hypersecretion of
water, Na, HCO3 and chlorides into the lumen and inhibits the
absorption of water and electrolytes by enterocytes. Results in fluid
and electrolyte loss leading to dehydration, electrolyte loss and
metabolic acidosis

Stable toxin=ST:
Acts differently viz. Guanylate cyclase and stimulates fluid
secretion
ETEC
PATHOGENESIS
 ENTEROPATHOGENIC E. coli (EPEC)
Pathogenesis
The infecting dose for infants is low. Causes watery
diarrhoea of few days duration
EPEC initially attach to enterocytes using pili of the bundle
forming pili(BFP) type to form clustered microcolonies on
the enterocyte cell surface of the small intestine.
The lesion then progresses with effacement/loss of the
microvilli and changes in the cell morphology including the
production of dramatic “pedestals” with the EPEC
bacterium at their apex.
The combination of these actions is called the attachment
and effacing (A/E) lesion
 ENTEROHEMORRHAGIC E. coli
(EHEC)/(VTEC)
Epidemiology
This disease occurs more in developed rather than
in developing countries.
EHEC was first recognized in the early 1980s when
outbreaks of HUS (haemolytic anemia, renal
failure, and thrombocytopenia) were linked to a
single E. coli serotype, O157:H7. Since then EHEC
disease has emerged as an important cause of
bloody diarrhoea.
Initially produces watery diarrhoea followed by
dysenteric illness
 ENTEROHEMORRHAGIC E. coli (EHEC)
Pathogenesis
EHEC produce both Shiga toxins(cytotoxin) and the A/E lesions
described above for EPEC.
EHEC primarily attacks the colon
The multiple extra-intestinal features such as HUS appear to be
the result of circulating Shiga toxin.
Shiga toxin production causes capillary thrombosis and
inflammation of the colonic mucosa, leading to a hemorrhagic
colitis.
Circulating Shiga toxin binds to renal tissue where its glycoprotein
receptor is particularly abundant, causing glomerular swelling and
the deposition of fibrin and platelets in the microvasculature.
How Shiga toxin causes haemolysis is less clear; perhaps the
erythrocytes are simply damaged as they attempt to traverse the
occluded capillaries.
EHEC
PATHOGENESIS
 ENTEROINVASIVE E. coli (EIEC)
EIEC infections are essentially restricted to
children under 5 years of age, living in
developing nations.
The infecting dose for EIEC is higher than it is
for Shigella.
Humans are the only known reservoir.
Patients develop watery diarrhoea initially
followed by dysentery
 ENTEROINVASIVE E. coli (EIEC)
Pathogenesis
Resistant to gastric acid and bile
Pass rapidly into the large intestine(colon)
Multiply, passing through the overlying mucous layer and
attach to the intestinal mucosal cells)
Invade the cells by induced endocytosis
Lyse the vacuole, multiply in the cytoplasm, rupture the cell
Then invade neighbouring cells
Spread and lead to tissue destruction, ulceration and
inflammation
Results in blood, pus and mucous in stools
 Vibrio cholerae
Causative agent of Cholera
Other Vibrio species are less important pathogens
Bacteriology
- Vibrios are curved, Gram-negative rods commonly
found in saltwater.
- They are highly motile with a single polar flagellum,
- Non–spore forming, oxidase positive, and can grow
under aerobic or anaerobic conditions at 37˚C.
- V. cholerae has a low tolerance for acid, but grows
under alkaline (pH 8.0 to 9.5) conditions that inhibit
many other Gram-negative bacteria
- There are over 150 O antigen serotypes, only two of
which (O1 and O139) cause Cholera
 Vibrio cholerae
3 serotypes of V. cholerae: Inaba, Ogawa,
Hikojima
- 2 biotypes: classical and El Tor
Other Vibrio species that can cause diarrhoea
include: Vibrio cholerae non-O1, Vibrio
parahaemolyticus
Curved Gram negative bacilli
 Vibrio cholerae
Epidemiology
Pandemic and epidemic potential
Epidemic cholera is spread by faecal-oral route
primarily by contaminated water under
conditions of poor sanitation
Man is the only natural host
Cholera is endemic in the Indian subcontinent
and Africa.
 Vibrio cholerae
Pathogenesis
To produce disease in healthy people, ingestion of large numbers of
bacteria(108-109) is required to overcome the acid barrier of the stomach.
Organisms multiply in the small intestine.
Penetrates mucus(mucinase)
Colonization of the entire intestinal tract from the jejunum to the colon by
V. cholerae requires organism adherence to the epithelial surface, most
probably by surface pili.
The outstanding feature of V. cholerae is the ability of virulent strains to
secrete the cholera toxin(CT), which is responsible for the disease cholera.
No mucosal damage occurs
The water and electrolyte shift from the cell to the intestinal lumen is the
fundamental cause of the watery diarrhoea of cholera.
 Vibrio cholerae
Cholera Toxin=potent enterotoxin
Main virulence factor
Encoded by chromosomal genes
Structure: polypeptide chains organized into two toxic subunits (A1, A2) and five
binding (B) units.
The B units bind to a GM1-ganglioside receptor found on the surface of many types
of cells. Once bound, the A1 subunit is released from the toxin molecule by
reduction of the disulfide bond that binds it to the A2 subunit, and it enters the cell
by translocation.
In the cell, it exerts its effect on the membrane-associated adenylate cyclase system
at the basolateral membrane surface.
This causes persistent activation of intracellular adenylate cyclase, which in turn
stimulates the conversion of adenosine triphosphate to cyclic adenosine 3,
5-monophosphate (cAMP). The net effect is excessive accumulation of cAMP at the
cell membrane, which causes hypersecretion of chloride, potassium, bicarbonate,
and associated water molecules out of the cell and prevents absorption of Na and
water.
V. CHOLERAE PATHOGENESIS
 Vibrio cholerae
Clinical features
Incubation period= 1-4 days
Cholera produces the most dramatic watery diarrhoea known.
Stool is watery with mucus flecks = rice water stool
May also develop nausea and vomiting
Intestinal fluids pour out in voluminous bowel movements; this
eventually leads to dehydration and electrolyte imbalance.
Severe dehydration, circulatory collapse, anuria and death may
occur
There is no fever, inflammation, or direct injury to the bowel
mucosa.
 RICE WATER STOOL

SEVERE DEHYDRATION
 Vibrio cholerae
Laboratory diagnosis
A bacteriologic diagnosis is accomplished by culture of V. Cholerae
from the stool/rectal swab.
If delay in transport to the lab, use transport medium eg. Cary
Blair transport medium and refrigerate sample
Enrichment broth : alkaline peptone water
The organism grows on common clinical laboratory media such as
blood agar and MacConkey agar
Its isolation is enhanced by the use of a selective medium
thiosulfate-citrate-bile salt-sucrose agar(TCBS).
Once isolated, the organism is readily identified by biochemical
reactions. Confirm with serological tests.
Microscopically: wet preparation shows no blood/leukocytes
 Vibrio cholerae
Treatment
Most important is fluid and electrolyte replacement
Antimicrobial therapy may shorten the duration of
illness and diminish fluid loss. Ciprofloxacin or
azithromycin may be used
Prevention
boiling or chlorination of water
Education of the community re. water handling and
storage
Vaccines
 Shigella
Clinical features
Is the classic cause of dysentery.
The illness begins as a watery diarrhoea but
progresses to an intense colitis with frequent
small-volume stools that contain blood and pus.
Characteristically, presents as a dysentery
syndrome—a clinical triad consisting of cramps,
painful straining to pass stools (tenesmus), and a
frequent, small-volume, bloody, mucoid discharge.
The vast majority of shigellosis cases resolve
spontaneously after 2 to 5 days.
 Shigella
Bacteriology
The most common species are S. sonnei and S. flexneri, S.
boydii, S. dysenteriae
Gram negative bacilli
Require selective media(Xylose lysine deoxycholate=XLD) to
culture the organism and inhibit normal flora.
Shigella species are non-lactose fermenters.
All Shigella species are nonmotile.
Shigella is an invasive bacterial pathogen. All species are
able to invade and multiply inside a wide variety of
epithelial cells, including their natural target, the
enterocyte.
S. dysenteriae type A1 (Shiga bacillus), the species that was
first discovered, is the most potent producer of Shiga toxin
 Stool wet preparation : demonstrates
Gram negative bacilli
leukocytes, erythrocytes

XLD=XYLOSE LYSINE
DEOXYCHOLATE
 Shigella
Epidemiology
Shigellosis is strictly a human disease with no
animal reservoirs.
Worldwide, it is one of the most common causes
of infectious diarrhoea in both developed and
developing countries.
The organisms can be readily transmitted by the
faecal–oral route through person-to-person
contact or by contamination of food or water.
The infecting dose is small, less than 200
organisms.
 Shigella
PATHOGENESIS
Shigella is acid-resistant and survives passage through the stomach to
reach the distal small bowel where the organism multiplies.
In 1-4 days, invasion and necrosis of the human colonic epithelium occurs.
This triggers an intense acute inflammatory response with mucosal
ulceration and abscess formation.
Shigella initially crosses the mucosal membrane by entering the
follicle-associated M cells of the intestine, which lack the highly organized
brush borders of absorptive enterocytes.
The Shigella adhere selectively to M cells and can transcytose through
them into the underlying collection of phagocytic cells.
Some Shigella produce Shiga toxin, which is not essential for disease, but
does contribute to the severity of the illness.
The original and most potent producer of Shiga toxin, S. dysenteriae type
1, is the only Shigella with a significant mortality rate among previously
healthy individuals. This is probably due to systemic effects of the toxin,
which can be the same as described for the EHEC, including HUS.
SHIGELLA
PATHOGENESIS
 Shigella
TREATMENT
Fluid replacement
Because the disease is usually self-limiting, the
beneficial effect of antibiotic treatment is in
shortening the illness and the period of excretion
of organisms.
Antibiotics such as quinolones and
third-generation cephalosporins have been used.
Antispasmodic agents may aggravate the
condition and are contraindicated in shigellosis.
 Shigella
Prevention and control
Provision of safe water
Adequate sanitation, sewage disposal
Fly control
Personal and food hygiene.
Screen and identify food handlers, subclinical
carriers
Isolate patients and safe disposal of excreta
No vaccine available
 Yersinia enterocolitica
Bacteriology
Yersinia are Gram negative coccobacilli and
tend to retain staining at the ends of the cells
(bipolar staining).
Pinpoint colonies on agar surface eg.
MacConkey agar
Gram negative bacilli
 Yersinia
Clinical features
Diarrhoea and vomiting
Abdominal pain and fever
Mesenteric adenitis(can mimic acute appendicitis)
Enteric fever syndrome
1-2 weeks after onset
– Arthralgia, arthritis, erythema nodosum, -
suggesting immunologic reaction to infection
 Yersinia
Epidemiology
Animal source
Humans acquire infection by consumption of
contaminated food or water.
Uncommon in South Africa
 Yersinia
Pathogenesis
Yersinia invade the M cells of the Peyer’s
patches.
Endotoxin and some exotoxin production
Multiply in the ileum, cause ulceration and
inflammation
Spread to mesenteric lymph nodes, rarely
bacteraemia
 Yersinia
Treatment
Self limiting-treat symptomatically
Antibiotics : especially if the patient is
septicaemic and has complicated disease
3rd generation cephalosporins plus
aminoglycoside, tetracyclines
 Campylobacter species
Bacteriology
Campylobacters are motile, curved, oxidase-positive,
Gram-negative bacilli
The cells have polar flagella and are often are attached
at their ends giving pairs “S” shapes or a “seagull”
appearance.
Campylobacter species associated with human disease
include C. jejuni, and C. coli
C. jejuni grows well only on enriched media eg.
Skirrow’s agar under microaerophilic conditions. That
is, it requires oxygen at reduced tension (5 – 10%).
Growth usually requires 2 to 4 days, sometimes as
much as a week.
CURVED GRAM NEGATIVE BACILLI
 Campylobacter species
Clinical features
C. jejuni infection begins with lower abdominal pain, then
diarrhoea over a matter of hours.
The diarrhoea may be watery or dysenteric, with blood and
pus in the stool.
Most patients are febrile.
Few patients develop bacteraemia
The illness resolves spontaneously after a few days to 1
week.
There is an association between C. jejuni infection and the
Guillain-Barré syndrome, an acute demyelinating
neuropathy that is frequently preceded by an infection.
Immunological basis for this association.
 Campylobacter species
Epidemiology
The primary reservoir is in animals and the bacteria are
transmitted to humans by ingestion of contaminated food
or by direct contact with pets.
Campylobacters are commonly found in the normal
gastrointestinal and genitourinary flora of sheep, cattle,
chickens, wild birds, and many others.
Domestic animals such as dogs may also carry the
organisms and probably play a significant role in
transmission to humans.
The most common source of human infection is
undercooked poultry, but outbreaks have been caused by
contaminated rural water supplies and unpasteurized milk.
 Campylobacter species
Pathogenesis
Infection is acquired by oral ingestion, followed by
colonization of the intestinal mucosa.
Affects the small intestine and colon=enterocolitis
Incubation period=3-5days
The bacteria have been shown to adhere to
endothelial cells and then enter cells in endocytotic
vacuoles.
The virulence determinants of this microorganism
remain uncertain.
 Campylobacter species
Treatment
Fluid and electrolytes
Antibiotics: only for severe or prolonged
infections
Erythromycin ( to reduce the fecal shedding )
– The drug of choice is usually erythromycin.
Patients may also respond to azithromycin and
ciprofloxacin
 Helicobacter pylori
Bacteriology
Spiral –shaped gram negative rod
Actively motile
Strong producer of urease
 Helicobacter pylori
Clinical features
Associated with peptic ulcer disease/gastritis
Helicobacter infections are limited to the mucosa
of the stomach, and most are asymptomatic even
after many years.
Burning pain in the upper abdomen/epigastrium,
accompanied by nausea and sometimes vomiting.
Ulcers may cause additional symptoms, depending
on their anatomic location.
 Helicobacter pylori
Epidemiology
The organism is found in the stomachs of 30 to 50% of
adults in developed countries and it is almost universal
in developing countries.
The exact mode of transmission is not known, but is
presumed to be person to person by the faecal–oral
route or by contact with gastric secretions.
Colonization increases progressively with age.
Once established, the same strain persists at least for
decades, probably for life.
H. pylori is the most common cause of gastritis, gastric
ulcers, and duodenal ulcers
 Helicobacter pylori
Diagnosis
Diagnosis is usually made by endoscopic examination, with
biopsy and culture of the gastric mucosa.
The H. pylori urease activity can be demonstrated in
biopsies in less than an hour.
Noninvasive methods include serology and a urea breath
test.
For the breath test, the patient ingests 13C- or 14C-labeled
urea, from which the urease in the stomach produces
products that appear as labeled CO2 in the breath.
Serology: detection of antibody directed against H. pylori
H. pylori stool antigen test
 Helicobacter pylori
Treatment
Proton pump inhibitors
Bismuth salts (eg, Pepto-Bismol)
Antibiotics treatment. Metronidazole,
clarithromycin, and amoxicillin have been
effective.
These combination regimens must be
continued for 7-14 days.
 Mycobacterium tuberculosis
Refer to previous lectures(Microbiology,
pathogenesis of Tuberculosis)
May cause abdominal tuberculosis which is a
form of extrapulmonary TB(EPTB)
 Pathophysiology
Acquire by ingestion: infected food/milk
Swallow infected sputum
Haematogenous spread
Lymphatic channels
Contiguous spread from adjacent focus
 Clinical symptoms/signs
Non-specific(fever, loss of weight)
Abdominal pain, vomiting
Abdominal lymphadenopathy
Ascites
‘Doughy’ abdomen
Abdominal masses, hepatosplenomegaly
 Diagnosis
High index of suspicion
History and clinical examination
Lab diagnosis: Microbiology, chemistry,
histopathology
Imaging: Ultrasound, CT scan
Surgery and biopsy
 Laboratory diagnosis
Microbiology: peritoneal fluid, tissue biopsy,
lymph node biospy
Microscopy: Auramine/Ziehl-Neelsen stains
Acid fast bacilli

Ziehl-Neelsen Auramine
 Laboratory diagnosis

Culture: solid/liquid culture medium

Lowenstein-Jensen

MGIT
 Laboratory diagnosis
Polymerase chain reaction(PCR)- TB
GeneXpert, Line probe assays

TB GeneXpert
 Laboratory diagnosis
Chemistry: Adenosine deaminase(ADA),
protein level in ascitic fluid
Histopathology: granulomas, acid fast bacilli
on biopsy samples