Download Streptococcus, Enterococcus and other Gram

Streptococcus, Enterococcus
and other Gram-positive cocci
Doç Dr Nevriye Gönüllü
Streptococcus
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Gram positive
Grow pattern
pairs, chains
Most species are facultatively anaerobes
Some grow only in atmosphere enhanced
with CO2 (capnophilic growth)
Nutritional requirements are complex
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Blood, serum enriched media
“Catalase-negative”
Classification of common streptococcal
pathogens
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Biochemical:
S.pyogenes
S.agalactiae
S.dysgalactiae
S.anginosus group
S.bovis
Viridans group
S.pneumoniae
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Serologic/Hemolysis:
Β/β
C,G/ β
A,C,F,G/β
D/ α
Nongroupable/α
Nongroupable/α
Streptococcus
Classification is complicated
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1.
2.
3.
3 different schemes are used
Lancefield groupings according to serologic
properties (A-H, K-M, O-V)
Hemolytic patterns: β, α & γ hemolysis
Biochemical properties
Streptococci and their diseases
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S. pyogenes (group
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A)
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Pharyngitis,
scarlet fever,
pyoderma,
erysipelas,
cellulitis,
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necrotizing
fasciitis,
streptococcal toxic
shock syndrome,
bacteremia,
rheumatic fever,
glomerulonephritis
Streptococci and their diseases
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S. agalactiae
(group B)
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Neonatal
infections
(meningitis,
pneumoniae,
bacteremia)
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Urinary tract
infections
Amnionitis,
Endometritis
Wound infections
Streptococcus pyogenes/physiology & structure
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Spherical cocci
Form short (clinical specimen) or long chains
(liquid media)
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Growth on enriched-blood agar media
White colonies
1-2 mm with large zones
of β-hemolysis
Encapsulated strains mucoid
Basic structure in the cell wall is
peptidoglycan as Gram+
group and type
specific antigens
Streptococcus pyogenes/physiology & structure
Group specific carbohydrate
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Within the cell wall
10 % of the dry weight
A dimer of N-acetylglucosamine and rhamnose
Is used to classify group A streptococci and
distinguish them from others
Streptococcus pyogenes/physiology & structure
Type specific proteins
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M protein
major type-specific protein
associated with virulent streptococci
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2 polypeptide chains
1. Highly conserved among all group A streptococci
2. Responsible for the antigenic variability
>100
serotypes
3. Are subdivided into class I (share exposed
antigens) and class II molecules (do not have
exposed shared antigens)
4. Only bacteria with class I M proteins cause
rheumatic fever
Type specific proteins
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T protein (trypsin-resistant): useful epidemiologic
marker
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Usefull when bacteria fail to express the M protein
Structure unknown
Epidemiologic classification based on identification
of specific M and T types by agglutination with M- or
T-specific antibodies
Will be replaced by sequencing the emm gene that
encodes the M protein
Streptococcus pyogenes/physiology & structure
Other cell surface components: components
of the cell wall
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M-like proteins
Lipoteichoic acid
F protein
Capsule
Capsule
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An outer hyaluronic acid capsule (repeating
molecules of glucuronic acid and Nacetylglucosamine)
Antigenically indistinguishable from
hyaluronic acid in mammalian connective
tissues
Functions: to prevent phagocytosis
Encapsulated strains are responsible for
severe systemic infections
Streptococcus pyogenes/Pathogenesis&Immunity
Virulence of S. pyogenes
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The ability of the bacteria
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to adhere to the surface of the host cells
Invade into the epithelial cells
Avoid opsonization & phagocytosis
Produce a variety of toxins & enzymes
Streptococcus pyogenes/Pathogenesis&Immunity
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Adherence to host cells is mediate by 10
different bacterial antigens
The most important:
lipoteichoic acid
M proteins
F protein
Invasion into epithelial cells is mediate by M
protein and F protein
Streptococcus pyogenes/Pathogenesis&Immunity
Pyrogenic exotoxins
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(Streptococcal pyrogenic exotoxin, Spes), originally called erythrogenic
toxins
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Produced by lysogenic strains, similar to the
toxin produced in Corynebacterium diphteriae
Four immunologically distinct heat-labile toxins
(SpeA, SpeB, SpeC and SpeF)
Superantigens (IL-1, IL-2, IL-6, TNF-β/α
Responsible for the streptococcal toxic shock
syndrome
Streptococcal pyrogenic exotoxin, (Spes)
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Act as superantigens, interacting with
macrophages and helper T cells
Secreted cytokines mediate important effects,
including shock and the organ failure seen in
patients with streptococcal toxic shock
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syndrome
Responsible for the rash observed in scarlet
fever
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Streptococcus pyogenes/Pathogenesis&Immunity
Streptolysin S & O
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Streptolysine S
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Streptolysine O
lyse erythrocytes
leukocytes
platelets
responsible for β-hem.
lyse erythrocytes
leukocytes
platelets
antibodies are formed
against
ASO test
Streptolysin S & O
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Streptolysin S:
Oxygen-stable
Nonimmunogenic
Produced in the
presence of serum
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Streptolysin O:
Oxygen-labile
Anti-ASO test useful for
documenting recent
group A streptococcal
infection
Antigenically related to
toxins produced
by:S.pneumoniae,
C.tetani, C.perfringens
Streptococcus pyogenes/Pathogenesis&Immunity
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Streptokinases
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Two forms: A & B
Mediate the cleavage of plasminogen, releasing
the protease plasmin that
Cleaves fibrin and fibrinogen, resulting in the lysis
of clots and fibrin deposits
Lyse blood clots, fibrin deposits, facilitate the rapid
spread of bacteria
Anti-streptokinase antibodies: useful marker for
infection
Streptococcus pyogenes/Pathogenesis&Immunity
Deoxyribonucleases
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Four immunologically distinct: DNAases A to D
Not cytolytic
Depolymerase free DNA in pus: reduce viscosity
of the abscess, facilitate spread
Developed antibodies: important markers of
cutaneous infections
Other enzymes
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C5a peptidase disrupts C5a (activate
phagocyting cells)
Hyaluronidase (spreading factor)
diphosphopyridine nucleotidase (DPNase): role
in pathogenesis is unknown
Epidemiology
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Colonize the oropharynx of healthy children
and young adults
Carriage 15-20%
Other streptococcal species (S.anginosus,
S.intermedius, S.constelatus) can carry
group-specific A antigen: do not cause
pharyngitis
Is transient (bacteriocins produced by other
streptococci suppress the growth)
Epidemiology
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Disease caused by recently acquired strains
Primarily infect children between 5-15 years
Spread from person to person through
respiratory droplets
Crowding, classrooms, daycare facilities
Particularly during the winter months
Epidemiology/ Soft-tissue infections
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Pyoderma, erysipelas, cellulitis
are preceded by skin colonization
after which the organisms are introduced into
the tissues through a break in the skin
Clinical diseases
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Suppurative streptococcal disease
Nonsuppurative streptococcal disease
Suppurative streptococcal disease
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Pharyngitis
Pyoderma
Erysipelas
Cellulitis
Necrotizing fasciitis
Streptococcal toxic shock syndrome
Other suppurative diseases bakteremia
Pharyngitis
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Develops 2 to 4 days
after exposure to the
pathogen
Sore throut, fever,
malaise, and headache
Posterior pharynx
erythematous
With exudate
Cervical
lymphadenopathy
Scarlet fever
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Complication of
pharyngitis
Strain lysogenized by a
temperate
bacteriophage
Stimulates production
of a pyrogenic exotoxin
Rash, Pastia’lines
Strawberry tongue
Pyoderma
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Purulent (“pyo“)
infection of the skin
(“derma“)
Infects exposed areas
(face, legs)
Introduced into the
subcutaneous tissue
Through a break in the
skin
Erysipelas
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Erythros “red“; pella
“skin“
Involved skin area is
typically raised
Young children and
older adults
Cellulitis
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Involves the skin and
deeper subcutaneous
tissues
Distinction of infected
skin is not as clear
Local and systemic
signs
Necrotizing fasciitis
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Also called
streptococcal gangrene
Occurs deep in the
tissue
Extensive destruction of
muscle and fat
“flesh-eating bacteria“
Gangrene and systemic
symptoms
Strept.toxic shock syndrome Other
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M serotypes 1 or 3
Prominent hyaluronic
acid capsules
Pyrogenic exotoxins:
SpeA and SpeC
Multisystem toxicity
Shock and organ failure
(kidney, lungs, liver)
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Puerperal sepsis
Pneumonia
Bacteremia in patients
with necrotizing fasciitis
or toxic shock
syndrome
Mortality 40%
Nonsuppurative streptococcal disease
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Rheumatic fever
Acute glomerulonephritis
Rheumatic fever
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Nonsuppurative
complication
Involvement of the heart
valves
Migratory arthritis
Associated with
streptococcal pharyngitis
If antibiotic prophylaxis is
not used
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Diagnosis is made on the
basis of clinical findings and
findings of a recent
S.pyogenes infection:
culture results
Detection of group A Ag
Elevation of ASO, antiDNase B, antihyaluronidase antibodies
Acute glomerulonephritis
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Acute inflammation of the renal glomeruli
Edema, hypertension, hematuria
Specific nephritogenic strains are associated
with this disease
Streptococcus pyogenes/IDENTIFICATION
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Microscopy: gram +cocci in pairs and chains
Antigen detection: use antibodies that react
with the group-specific carbohydrate in the
bacterial wall
Enzyme immunassay (EIA) or bound to latex
particles
Sensitivity is low (90%): all negative results
must be confirmed by culture
Streptococcus pyogenes/IDENTIFICATION
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Culture: specimens must be obtained from the
posterior oropharynx or skin lesions
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Nutritionally enriched agar media with sheep
blood
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Selective media (media with “bactrim”)
Prolonged incubation
Identification
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Susceptibility to bacitracin
L-pyrrolidonyl arylamidase (PYR): hydrolyzes
L-pyrrolidonyl-β-naphtylamide releasing βnaphthylamide
Antibody detection:antibodies against
streptolysin O (the ASO test); appear 3-4
weeks after the exposure
Anti-DNase B test if glomerulonephritis is
suspected
Treatment
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Penisilin
Erythromycin or oral cephlosporin
Newer macrolides
Drainage and surgical debridement
Rheumatic fever: Longterm antibiotic
prophylaxis
Streptococcus agalactiae (Group B)
The only species that carries the group B
antigen
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physiology & structure
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Gr + cocci
Short or long chains (indistinguishable from S. pyogenes)
Buttery colonies, narrow zone of β-hemolysis
Subdividing
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The B antigen
group specific
Capsular polysaccharides
type-specific
C protein (surface protein)
Streptococcus agalactiae/IDENTIFICATION
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Microscopy
Culture:
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Readily grow on a nutritionally enriched medium
Large colonies
β-hemolysis may be absent
selective broth
medium with antibiotics
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Identification
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Preliminary identification
(+) CAMP test,
hydrolysis of
hippurate
Pathogenesis
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Genital colonization with group B streptococci
has been associated with increased risk of
premature delivery
Serotypes Ia, III and V are most commonly
associated with colonization and disease
Colonize lower gastrointestinal tract and
genitourinary tract
60% of infants born become colonized with
their mothers’ organisms
Early/Late –onset disease
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Septicemia and meningitis in newborns
Early: infants younger than 7 days
Late: 1 week-3 months
In adults:urinary tract infections, wound
infections, skin and soft-tissue infections
Diagnosis
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Antigen detection: latex agglutination
Culture: enriched medium
Beta-hemolysis
Nucleic acid-based tests: PCR
Identification: CAMP test or hydrolysis of
hippurate
Treatment
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Penisilin: needs greater MIC
Tolerance to penicilin has beem reported
Combination of penicillin and aminoglycoside
in serious infections or vancomycin in
penicillin allergy
Prevention: all pregnant women should be
screened for colonization at 35-37 weeks of
gestation
Other beta-hemolytic streptococci
Group C, F and G are most commonly
associated with human disease
2 species of particular importance
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S. anginosus
S. dysgalactiae
Posses group A, C, F or G capsular
polysaccaride
Abscess formation, bacteremia
Viridans Streptococci
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A heterogeneous colection of α-hemolytic and
nonhemolytic streptococci
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Their name is derived from viridis (Latin for
green)
Produce a green pigment on blood agar
media
More than 20 species; are classified into five
subgroups:
Viridans Streptococci: subgroups
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Anginosus: S.anginosus, S.intermedius
Mitis: S.mitis, S.pneumoniae, S.sanguis
Mutans:S.mutans, S.sobrinus
Salivarius: S.salivarius, S.vestibularis
Bovis:S.bovis, S.equinus
Ungrouped: S.suis
Viridans Streptococci: culture
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Require complex media supplemented with
blood products and an incubation atmosphere
at 5-10 % CO2.
Some strains are “nutritionally deficient
streptococci“ :
Can grow only in the presence of exogenously
supplied pyridoxal (the active form of vitamin B6)
These organisms can grow in blood cultures, but
cannot grow when subcultured (unless pyridoxal
supplemented media are used).
Viridans Streptococci: colonization
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Colonize the oropharinx, gastrointestinal tract,
genitourinary tract
Rarely found on the skin surface, because fatty
acids are toxic to them
Viridans Streptococci: infections
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Associated with dental caries, subacute
endocarditis, and suppurative intraabdominal
infections
Subacute bacterial endocarditis is associated
with S.gordonii, S.mitis, S.mutans, S.oralis,
S.sanguis
Antibiotic resistance
In the past they were highly susceptible to
penicillin (MIC <0.1µg/ml)
„ Moderately and highly resistant strains have
become common
„ Treatment:
Penicillin+aminoglycoside
Broad spectrum cephalosporin+vancomycin
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Streptococcus pneumoniae
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Isolated independently by Pasteur and
Steinberg more than 100 years ago
Is still a leading cause of morbidity and
mortality
Encapsulated, Gr + coccus
Oval or lancet-shaped cells, in pairs or short
chains
α-hemolytic: production of pneumolysin , an
enzyme that degrades hemoglobin producing a
green product
Streptococcus pneumoniae
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Can grow only on enriched media (with blood
products)
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Catalase (-)
Polysaccharide capsule is used for the
serologic classification:
90 serotypes
Capsular polysaccharides are used in vaccines
Streptococcus pneumoniae: cell wall
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Peptidoglycan layer is typical of gram-positive
cocci
Teichoic acid, rich in galactosamine and choline
C polysaccharide (CRP): precipitates a serum
globulin fraction (C-reactive protein)
F antigen: lipid-bound teichoic acid in the
bacterial cytoplasmic membrane
S. pneumoniae / diseases
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Pneumoniae
Meningitis
Sinusitis
Otitis media
Bacteremia
Streptococcus pneumoniae/Pathogenesis&Immunity
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The disease manifestations are caused
primarily by the host response to infection
rather than the production of organism-specific
toxic factors
Streptococcus pneumoniae/Pathogenesis&Immunity
Colonization and migration
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S.pn colonizes the oropharynx
Can spread to the lungs, paranasal
sinuses, middle ear, blood stream
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By means of:
Surface protein adhesins
secretory IgA (sIgA) protease
Pneumolysin: a cytotoxin similar to the
streptolysin O in S.pyogenes
Streptococcus pneumoniae/Pathogenesis&Immunity
Tissue destruction
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Mobilization of inflamatory cells characteristic of
pneumococcal infections
„ Teichoic acid and peptidoglycan fragments:
activate alternative complement pathway producing
C5a
„ Pneumolysin: activates the classic complement
pathway, resulting in prodution of C3a and C5a
„ H2O2 production: lead to tissue damage
„ Phosphorylcholin: binds phosphodiesteraseactivating factor, allowing bacteria to enter host
cells
Streptococcus pneumoniae/Pathogenesis&Immunity
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Phagocytic survival
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Survive phagocytosis because of the antiphagocytic
protection afforded by its capsule
Pneumolysin mediates suppression of the
phagocytosis
The virulence is a direct result of this capsule
Epidemiology
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Common inhabitant of the throat and
nasopharynx in healthy peaple
A 5-75% incidence of such carriage has been
reported
Colonization more common in children than
in adults
Occurs at approximately 6 months of age
Epidemiology
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Pneumococcal disease occurs when
organisms colonizing the nasopharynx and
oropharynx spread to distal locci:
The lungs (pneumonia)
Paranasal sinuses (sinusitis)
Ears (otitis media)
Meninges (meningitis)
Bacteremia
Epidemiology
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A common cause of
bacterial pneumonia
Meningitis
Sinusitis
Otitis media
Bacteremia
Streptococcus pneumoniae/IDENTIFICATION
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Microscopy
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Culture:
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Lancet-shaped, Gr (+) diplococci, unstained
capsule (Gram stain with “quellung” reaction)
Enriched supplemented medium with blood
Selective medium with gentamicin
Identification
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Bile solubility test
Optochin (ethylhydrocupreine dihydrochloride)
Quellung reaction
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Polyvalent anticapsular
antibodies are mixed
with the bacteria
Streptococcus pneumoniae-Antibiotic resistance
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Resistance to multiple antibiotics, including
penicillin was reported
Mechanism: Decreased affinity of the
antibiotic for the penicillin-binding proteins
present in the bacterial cell wall
Enterococcus
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The enterococci (“enteric cocci”) were
previously classified as group D streptococci
They possess the group D cell wall antigen
(glycerol teichoic acid)
Are distinct from other group D streptococci
(nonenterococcal group D streptococci e.g.,
Streptococcus bovis)
1984: the new genus Enterococcus
Enterococcus
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Most frequently isolated & most commonly
responsible for human disease with
streptococcus among gram-positive cocci
16 species in the genus
E. faecalis & E. faecium are most commonly
isolated
Enterococcus/physiology & structure
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They can not be differentiated from S.
pneumoniae in microscope
Facultatively anaerobic
Optimal growth temp.= 35 oC (10oC to 45oC)
White, large colonies on blood agar (after 24h)
Nonhemolytic (or α or β-hemolysis)
Grow in the presence of
‰ 6.5 % NaCl, tolerate 40 % bile salts,
hydrolyse esculin
Enterococcus/Pathogenesis&Immunity
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Are commensal with
limited potential for
causing disease
Do not possess toxins
Cannot avoid being
engulfed & killed by
phagocytic cells
BUT,
Cause
Serious
Disease
Enterococcus/Pathogenesis&Immunity
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Virulence factors
Adhesive factors
‰ Secrete extracellular proteins
(cytolysin)
‰ Bacteriocins
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Inherently resistant to many
antibiotics
Epidemiology
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Are enteric bacteria
Recovered in feces collected from humans
and animals
E.g., E.faecalis 107 per gram feces
E. faecium are less frequently
E.gallinarum and casseliflavus: colonize the
intestine in small numbers; resistant to
vancomycin; can be confused with the more
important species
Enterococcus/Clinical Diseases
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Can cause life-threatening infections
One of the most feared nosocomial
pathogens
10% of all nos. infct.
Most commonly involved sites
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Urinary tract
Blood stream
A sever complication: endocarditis( following
bacteremia)
Enterococcus/Laboratory diagnosis
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Grow readily on nonselective media
Resemble S. pneum.
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Differentiation
resistant to optochin
don’t dissolve when
exposed to bile
hydrolyze PYR
pyrolidonyl-β-naphthylamide
Other Catalase-negative Gram positive
cocci
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Leuconostoc (VaR)
Pediococcus (VaR)
Lactococcus
Aerococcus (air coccus)