Aerobic Gram Positive Bacilli PDF

Summary

This document provides information on aerobic gram-positive bacilli, including various species and their characteristics. It discusses their role in the body, including as normal microbiota and pathogens.

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Aerobic Gram Positive Bacilli
RAQUEL M. FERNANDEZ, RMT, MSPH
Aerobic Gram positive Bacilli
Spore former: Bacillus
Non-spore former: Corynebacterium, Arcanobacterium, Rhodococcus,
Listeria, Erysipelothrix, Gardnerella, Rothia,
Branching non-spore former: Actinomycetes, Nocardia
Some are rarely encountered but cause significant disease
Most are considered contaminants or commensals
Non-Spore Forming, Non-Branching Catalase
Positive Bacilli
Corynebacterium
More than 60 species , 40 of which are clinically significant
Most are normal microbiota of skin and mucous membranes
Cell walls contain m-DAP
All are cat+ and non-motile
Divided into lipophilic and non-lipophilic
Lipophilic are fastidious and grow slowly (at least 48h) on standard
media
On Grams stain are slightly curved, club-shaped bacilli
Corynebacterium
Coryneform-like isolates are unable to be identified to the species
level without 16s rRNA sequencing
Species include: C. bovis, C. ulcerans, C. xerosis, C. jeikeium, C.
pseudodiphtheriticum, C. pseudotuberculosis
Corynebacterium diphtheriae
VIRULENCE FACTORS.
Diphtheria toxin.
Produced by strains infected with lysogenic β-phage, which carries the tox
gene
Non-toxigenic strains can be converted to tox+ by infection with appropriate
β-phage
Only toxin producing C. diphtheria causes diphtheria
Composed of 2 fragments A and B linked together by a disulfide bridge
Fragment A is responsible for cytotoxicity and Fragment B binds to receptors
on the eukaryotic cells
Potent and lethal in humans in 130ng/kg of body weight
Acts by blocking protein synthesis
Excreted by the bacterial cell and is non-toxic until exposed to trypsin
Clinical Significance: Respiratory diphtheria
Humans are the only natural host for this organism
The bacteria is carried on the URT and spreads by droplet or hand to
mouth contact
Incubation 2-5 days
Illness begins gradually and is characterized by low-grade fever,
malaise and mild sore throat
The most common site of infection is the tonsils or pharynx
Organisms rapidly multiply on epithelial cells
Clinical Significance: Respiratory diphtheria
Necrotic cell and exudate forms pseudomembrane
Toxin causes demyelinating peripheral neuritis which may result in
paralysis following the acute illness
Clinical Significance: Cutaneous diphtheria
Prevalent in the tropics
Toxin is also absorbed systematically
Consists of non-healing ulcers with a dirty gray membrane
Treatment is by administration of anti-toxin produced in horses
Drug of choice is P or E
Lab DX
MICROSCOPY
CULTURE
TOXIGENECITY TESTS
Microscopy
Highly pleomorphic gram positive bacillus that appears in palisades or
as individual cells lying at sharp angles to another in V and L forms
Club-shaped swellings and beaded forms are common
Organism often stain irregularly when stained with methylene blue
The metachromatic areas of the cell stain more intensely than other
parts called Babes-Ernst granules
Babes-Ernst granules are nutrient reserves
Culture Characteristics
Grow best at aerobic conditions at 37°C
Multiplication can occur within the range of 15-40°C
Require 8 essential amino acids
Better growth is usually obtained on a medium containing blood or
serum
May have very small zone of β-hemolysis
CTBA, Loeffler’s serum or Pai agars can be used
Cat+ and non-motile
C. diphtheria is urease negative, ferments glu and maltose with acid
but no gas, reduces nitrate
CTBA
A modification of Tinsdale medium
Contains sheep RBC, bovine serum,
cysteine and potassium tellurite
Both selective and differential
Form black or brownish colonies
from the reduction of tellurite
A brown halo surrounding the
colony due to cystinase activity are
produce by C. diphtheria, C.
ulcerans and C. pseudotuberculosis
Toxigenecity test
Addition of iron to iron-starved
culture inhibits toxin production
quickly
In vitro: ELEK TEST
Other methods include ELISA,
immunochromatographic strip
assays, PCR
Listeria monocytogenes
General characteristics
Comprises 6 species, only L. monocytogenes and L. ivanovii are
pathogenic
Found in the environment from soil, water, vegetation and animal
products such as raw milk, cheese, poultry and processed meats
Has been isolated from crustaceans, flies and ticks
Causes serious infection primarily of neonates, pregnant women, the
elderly and immunocompromised host
Virulence factors
Listeriolysin O (hemolysin)
Catalase superoxide dismutase
Phospholipase C
Surface protein p60
Clinical infections
Listeriosis in pregnant women
Most commonly in the 3rd trimester responsible for spontaneous
abortion and stillbirth
Flu-like illness with fever, headache and myalgia
Often infection is self-limited because infection is eliminated when
birth occurs
Disease in the newborn
Serious disease, fatality up to 50%
2 Forms: early onset and late onset
Early Onset: intra-uterine infection or infection shortly after birth.
Sepsis is often the result.
Late Onset: several days to weeks after birth. Meningitis is often the
manifestation.
Disease in Immunocompromised
Most commonly CNS infection and endocarditis
Infection is acquired by eating food contaminated with L.
monocytogenes
Amp is the drug of choice
Lab DX
MICROSCOPY. Appears as gram positive coccobacillus found singly, in
short chains and in palisades
CULTURE.
Grows well on SBA and chocolate agar, nutrient agar, BHIB and Thio broth.
Colonies are small, round, smooth and translucent
Surrounded by a narrow zone of β-hemolysis
Growth occurs over a wide range (0.5-45°C); Optimum: 30-35°C
Cold enrichment may help
IDENTIFICATION.
Catalase+, tumbling motility in wet smear, umbrella pattern in motility
medium at room temp. but not at 35°C
Lab DX
IDENTIFICATION.
Hippurate hydrolysis +, BE +, CAMP +
Block type of hemolysis on CAMP
Produces acid from glucose
VP and MR +
Non-Spore Forming, Non-Branching Catalase
Negative Bacilli
General Characteristics
3 species: rhusiopathiae, tonsillarum and inopinata
E. rhusiopathiae is the only pathogenic
Gram positive, catalase negative, non-spore-forming, pleomorphic
rod with a tendency to form long filaments
Found worldwide in animals swine, birds and fish
Usual route is through the cuts and scratches on the skin
Organism is resistant to salting, pickling and smoking
Erysipelothrix rhusiopathiae:
General characteristics
Gram positive, non–spore-forming, pleomorphic rods (can produce long
filaments)

Distributed in nature

Can cause disease in animals (swine, turkey, sheep); swine is the main
reservoir

Humans acquire the infection through occupational exposure, such as cuts &
scratches (fish handlers, animal products)
Erysipelothrix rhusiopathiae:
Clinical Infections
Erysipeloid
Self-limiting localized infection at the site of inoculation
Produces painful swelling, usually on the hands or fingers
Heals within 3 to 4 weeks
Treat with penicillin, cephalosporin, erythromycin
Endocarditis
May occur in those who have had valve replacements
Disseminated infections may occur, but rarely due to exacerbation of
erysipeloid lesions
Laboratory Diagnosis:
Erysipelothrix rhusiopathiae
Colony Morphology
CO2 is required
Grows on blood or chocolate agar
Colonies may appear gray or
translucent, pinpoint
Alpha hemolysis or nonhemolytic
Laboratory Diagnosis:
Erysipelothrix rhusiopathiae
Microscopic Morphology
Pleomorphic,
Gram-positive thin rods that may
form long filaments or short rods
Arranged singly, in short chains, or
in a V shape
Decolorizes easily so it may appear
gram variable
Laboratory Diagnosis:
Erysipelothrix rhusiopathiae
Identification
Catalase, nitrate, urease negative
Non-motile
Production of H2S on TSI
VP negative, does not HOH Esculin
Test tube brush growth in
semisolid motility media
2 colony types: Pin point, non-
hemolytic, glistening colonies or
the larger, rough colonies with
matte, curled and irregular edges
Characteristics of Corynebacterium,
Listeria, and Erysipelothrix
Gardnerella vaginalis
Member of the normal flora of the female genital tract
Associated with bacterial vaginosis
Foul odor
Vaginal pH > 4.5
Laboratory Diagnosis:
Gardnerella vaginalis
Wet Prep
Look for clue cells
Large epithelials with various
bacterial types on edges
Gram stain
Small, thin
Gram variable rods
Laboratory Diagnosis:
Gardnerella vaginalis

Cultural Characteristics
Growth on BAP, CA
No growth on MAC
Human blood bilayer tween “V” agar
Beta-hemolytic
Requires a CO2 environment
Catalase negative
 Gardnerella Vaginitis
Gram-variable-staining rod, facultative anaerobic bacteria
(actually has a Gram-positive cell wall, but because the cell
wall is so thin it can appear either Gram-positive or Gram-
negative under the microscope).
Small (1-1.5 µm diameter) non-spore forming, non-motile
coccobacilli.
Previously classified as Haemophilus vaginalis and afterwards
as Corynebacterium vaginalis.
 Gardnerella Vaginitis
Growth: grows as small,
circular, convex, gray
colonies on chocolate agar;
it also grows on HBT agar.
Can cause bacterial
vaginosis in some women
as a result of a disruption
in the normal vaginal
microbiota
 Can be isolated from other Areas
Typically isolated in
genital cultures. May
also be detected in
other samples from
blood, urine, and
pharynx
 Morphology
Small, Gram negative,
on motile
Pleomorphic rod which
shows metachromatic
granules
Presence of Clue cells
 Gram Stain still the simple in diagnosis of
Bacterial Vaginosis
The Centers for Disease
Control and Prevention
(2010) also recommend
the gram stain as the
gold standard for
diagnosis of bacterial
vaginosis
 Culturing
Grows on Blood and
Chocolate Agar
Hemolytic colonies on
Human and Rabbit
blood agar,
Catalase –
Oxidase -
 Symptoms
Up to 50% of women
diagnosed with bacterial
vaginosis do not have
symptoms. In others, it causes
an unpleasant "fishy" vaginal
odor and a yellow or white
vaginal discharge. For some
women, these symptoms are
especially bothersome during
or after intercourse.
 Observation of Vaginal Discharge

The discharge seen in bacterial
vaginosis tends to be thinner than
the "cheesy," thick discharge seen
in vaginal yeast (Candida)
infections. Bacterial vaginosis
usually does not cause significant
irritation of the vulva or pain
during intercourse. If you have
these symptoms, your doctor will
check for other possible causes.
 No perfect test
There is no perfect test, but if
you have three of the following
four criteria, it is highly likely
that you have bacterial
vaginosis:
1 White, thin, coating on your
vaginal walls during the pelvic
exam

44
 Diagnosis
2 pH test of vaginal discharge
that shows low acidity (pH
greater than 4.5)
3 Fishy odor when a sample of
vaginal discharge is combined
with a drop of potassium
hydroxide on a glass slide (the
"whiff test")
 Clue cells
4 Clue cells (vaginal
skin cells that are
coated with bacteria)
visible on microscopic
exam of vaginal fluid
 Newer methods in diagnosis of Genital
Infections
DNA probes have been developed to directly detect the
presence of Candida, Trichomonas and Gardnerella, thus
providing a more objective diagnosis. Since Gardnerella is a
normal part of the vaginal flora, the DNA probe test is designed
to be relatively insensitive, detecting only pathogenic levels of
Gardnerella. The Affirm VP III Microbial Identification System
(Becton Dickinson) is a commercially available DNA probe
office-based test kit that simultaneously detects the presence of
Gardnerella, Trichomonas and Candida.

47
 Treatment
Commonly treat bacterial vaginosis with metronidazole
(Flagyl or MetroGel-Vaginal) or clindamycin (Cleocin). Either
can be taken by mouth or applied as a vaginal cream or gel.
However, the U.S. Centers for Disease Control and
Prevention (CDC) recommends that all pregnant women with
symptoms be treated with oral medications because the
medications are safe and work better than vaginal creams or
gels.
 Treatment
Studies show that a seven-day
treatment with oral
metronidazole or a five-day
treatment with metronidazole
vaginal gel is equally effective in
non-pregnant women.
Clindamycin vaginal cream is
slightly less effective than
either type of metronidazole.
 Complications
The bacterial vaginosis has
been associated with the
development of pelvic
inflammatory disease and
other infections after
endometrial biopsy, surgical
abortion, hysterectomy,
intrauterine device placement,
Caesarean section and uterine
curettage.
Arcanobacterium
The genus contains 6 species of which 3 are medically important:
A. haemolyticum
A. pyogenes
A. bernardiae
All are catalase negative, pleiomorphic rods that can branch
Frequently, a black opaque dot is observed on the agar when
scraped
Pits agar
Arcanobacterium haemolyticum
Diseases associated include:
Pharyngitis
Desquamation of skin of the hands and feet
Soft tissue infections, sepsis, endocarditis
Produces small colonies with narrow zone of β-hemolysis after 24-48
hours of incubation
Lipase+, Lecithinase+
Pen Resistant, Erythromycin is the drug of choice
 Clinically important Gram positive bacilli

Spore forming Acid-fast bacilli
1. Bacillus (O2) 1.Mycobacterium
2. Clostridium (O2) 2.Nocardia
Non spore forming
1.Listeria Non-acid-fast branching
2. Erysipelothrix filamenous bacilli
3.Corynebacterium 1.Actinomyces
4. Propionibacterium
Spore Forming, Non-Branching Catalase
Positive Bacilli
 Gram-Positive Spore-Forming
Bacilli
Gram positive, motile, rod shaped
-Bacillus
 GENUS BACILLUS
Aerobic
Catalase positive
Not fastidious
 1.BACILLUS
Bacillus anthracis
– Human pathogen
– Isolation also considered to be clinically significant
– Zoonosis
Bacillus cereus
– Environmental organism
– Contaminates food
– Common cause of food poisoning
Bacillus (Geobacillus)
stearothermophilus
– Tolerates very high temperatures
– Used for quality control of autoclaves
 a.Bacillus anthracis
Large bacilli of 3-5
m
Single or paired in
clinical isolates
Polypeptide capsule
and exotoxins
Highly resistant
central spores
Anthrax toxin
Consists of 3 proteins: PA, LF, and EF
PA serves as the binding molecule for EF and LF
PA + EF = Edema
PA + LF = Death
 Anthrax

Spore of B.anthracis
Duration of life
(> 60 years) soil
Medusa head colonies of Bacillus anthracis
 Anthrax
Zoonotic disease of herbivorous livestock
Anthrax - Epidemiology
 Anthrax
Pathogenesis and clinical presentations
Cutaneous
Cutaneous anthrax
anthrax
About
About20%
20%mortality
mortality Virulence factors
Capsule
(antiphagocytic)
Toxin
(oedema & death)

Inhalation anthrax
Inhalation anthrax Gastrointestinal
Gastrointestinal anthrax
anthrax
Highmortality
High mortality High
Highmortality
mortality
 Cutaneous anthrax

« malignant pustule »

Incubation 2-3 days

erythematous papule

Increasingly necrotic  later ruptures to form

a painless black eschar
 Gastro-intestinal anthrax

Contaminated meat

Asia, Africa

Cardiovascular collapse within few hours

and death
 Pulmonary anthrax
Toxemia, capillary thrombosis, cardiovascular shock
 Injectional anthrax
Injectional anthrax is characterized by soft tissue infection associated
with “skin popping” or other forms of injection drug use
Results from the direct injection of the spores into tissue
Can be associated with necrotizing fasciitis, organ failure, shock,
coma, and meningitis,
Has a much higher rate of mortality than cutaneous
Have not been associated with black eschar formation
 Bioterrorism
and Anthrax bacillus
 Anthrax - Diagnosis
Specimen
– Aspirate or swab from cutaneous lesion
– Blood culture
– Sputum
Laboratory investigation
– Gram stain
– Culture
– Identification of isolate
Anthrax – treatment and prevention
Penicillin
(Tetracycline /chloramphenicol)
Erythromycin,Clindamycin
Prevention
– Vaccination of animal herds
– Proper disposal of carcasses (burning
or decontamination before burial)
Active immunization with live attenuated
bacilli
 b. Bacillus cereus
Large, motile, saprophytic bacillus
Heat resistant spores
Airborne and dust-borne contaminants
Pre formed heat and acid stable toxin (Emetic syndrome)
Heat labile enterotoxin (Diarrhoeal disease)
Multiply readily in cooked foods (Rice, potato and meat)
Lab diagnosis – Demonstration of large number of bacilli
in food
Bacillus cereus
clinical presentation Gastroenteritis
Gastroenteritis
EMETIC FORM DIARRHOEAL FORM

Incubation period > 6 hours
Incubation period < 6 hours Diarrhoea
Severe vomiting Lasts 20-36 hours
Lasts 8-10 hours
Non-spore-forming, Branching Aerobic Gram
Positive Bacilli: Aerobic Actinomycetes and
Nocardia
Nocardia
Aerobic, branched, beaded gram positive bacilli
Beads are not usually spaced at consistent intervals
Finely beaded, branching rods, weakly acid-fast
Grow on standard, non-selective media after a week or more
Commonly found in soil
Infections resemble fungi and usually occur in immunocompromised
patients
Species include: N. asteroides, N. brasiliensis, N. farcinica and N. nova
Virulence factors
No virulence factors have been identified
Correlated with alterations in the cell wall components
Produces SOD and catalase
Produces iron-chelating compound called nocobactin
Clinical infections
2 routes: pulmonary and cutaneous
Pulmonary by inhalation of the organism present in dust or soil
usually in immunocompromised persons
Mortality rate is high and those who survive often suffer significant
damage
Pulmonary infections
Commonly caused by N. farcinica and N. ciriacigeorgica
Common manifestation is confluent bronchopneumonia
Disease progresses more rapidly than TB and is measured in months
rather than years
In acute form, time course is a matter of weeks
Initial lesion starts with a focus of pneumonitis that advances to
necrosis
There is little inflammatory response or scarring, no encapsulation of
the abscess and no granuloma formation, no sulfur granules or sinus
tract formation
Cutaneous infections
Occurs following inoculation in the skin and SQ tissues, usually skin
and feet
N. brasiliensis is the most frequent cause
Lesions are termed actinomycotic mycetomas
Pus may be pigmented and contain sulfur granules (appearing yellow
or orange hence the term)
Lab DX
MICROSCOPY.
Beaded branching filaments often seen in sputum and exudates or aspirates
from skin and abscesses
Weakly acid fast (0.5-1% sulfuric acid)
Granules (when separated from pus) can be seen in wet mounts from
cutaneous infection
CULTURE
Oxidative type metabolism
Do not require specific growth factors, grow well on common media
Growth occurs after 3-6 days
TM may be used
Lab DX
CULTURE
Colonies are chalky, matte, velvety appearance and might be pigmented
Can have dry, crumbly appearance
Colonies may reveal presence of aerial hyphae
IDENTIFICATION.
Substrate hydrolysis (casein, tyrosine, xanthine)
CHO utilization
Antimicrobial susceptibility profile
Fatty acid analysis by HPLC
16s rRNA gene sequencing
Treatment
Drainage and surgery along with antimicrobials
R to Pen but susceptible to sulfonamides
Lab results are ABSOLUTELY essential for proper antimicrobial
treatment
Other Genera of the Actinomycetes
Actinomadura
Streptomyces
Gordonia
Tsukamurella
Rhodococcus
Trophyrema whipplei
MYCOBACTERIA
MYCOBACTERIUM
Aerobic bacilli –non spore forming
non motile
Cell wall –rich in lipids
Acid-fast bacilli
Very slow growing
 MYCOBACTERIA ASSOCIATED WITH
HUMAN DISEASE
Mycobacterium Environmental contaminant Reservoir
M tuberculosis No Human
M bovis No Human, cattle
M leprae No Humn
M kansasii Rarely Water, cattle
M marinum Rarely Fish, water
M scrofulaceum Possibly Soil, water
M avium Possibly Soil, water, birds
intracellulare
M ulcerans No Unknown
M fortuitum Yes Soil, water, animals
M chelonae Yes Soil, water, animals
 CLASSIFICATION OF MYCOBACTERIA
ASSOCIATED WITH HUMAN DISEASE
Mycobacterium Clinical significance Pigmentation Growth
Unclassified
M tuberculosis , M bovis Strict pathogens No No
M ulcerans
M leprae Strict pathogen - -
Runyon Group 1
M marinum , kansasii Usually pathogenic Photochromogens slow
Runyon Group 2
M scrofulaceum Rarely pathogenic Scotochromogens slow
Runyon Group 3
M avium intracellulare Pathogenic in No slow
immunocompromised
Runyon Group 4
M fortuitum, M chelonae Rarely pathogenic No ‘rapid’
Mycobacterium tuberculosis
Causes tuberculosis
Classic human disease
Pathogenesis
Transmission
Clinical presentations
Diagnosis
Treatment
Prevention
 Pathogenesis
Inhaled aerosols
Engulfed by alveolar macrophages
Bacilli replicate
Macrophages die
Infected macrophages migrate local lymph nodes
Develop Ghon’s focus Primary complex
Cell mediated immune response

stops cycle of destruction and spread
Viable but non replicating bacilli present in macrophages

EVIDENCE OF INFECTION WITH M TUBERCULOSIS
Chest x-ray / positive skin test
 CLINICAL PRESENTATION
Pulmonary tuberculosis

Primary complex
Asymptomatic
HEALS

Acute pulmonary disease REACTIVATION
Systemic spread Post-primary
tuberculosis
Aymptomatic /symptomatic

LATER DISEASE MILIARY TUBERCULOSIS
Renal / CNS etc Pulmonary
meningitis
 DIAGNOSIS
Pulmonary tuberculosis

1 1 Primary complex
Asymptomatic
HEALS
2
3

Acute pulmonary disease REACTIVATION
Systemic spread Post-primary
tuberculosis
Aymptomatic /symptomatic

LATER DISEASE MILIARY TUBERCULOSIS
3
Renal / CNS etc Pulmonary 3
meningitis
 DIAGNOSIS
1. Evidence of infection
a. Chest x-ray - hilar lymphadenopathy
calcification of primary focus/LN
b. Delayed hypersensitivity response to purified protein derivative
(PPD) MANTOUX /HEAF TEST
2. Evidence of active disease
a. Sputum for AFB positive
3. Evidence of active disease
a. Indirect evidence of infection (Mantoux)
b. Direct evidence of infection PCR / culture
c. Histo-pathological evidence
TREATMENT
Anti-tuberculous drugs
INAH
Rifampicin
Ethambutol
Pyrazinamide
DOT
Multi-drug resistant tuberculosis
PREVENTION
Incidence declined before availability of anti-tuberculous drugs
Improved social conditions - housing /nutrition
Case detection & treatment
Contact tracing
Evidence of infection / disease
Treatment of infected / diseased contacts

ROLE OF IMMUNIZATION
BCG (bacillus Calmette Guerin)
Mycobacterium leprae
Acid fast bacilli
Strict human pathogens
Cannot be cultivated in-vitro
Armadillo’s used for obtaining M leprae
Transmission - ? Air borne
Low infectivity - prolonged contact
required
Spectrum of clinical presentations
dependent on host –parasite interactions
Borderline Borderline
Tuberculoid Lepromatous
Tuberculoid lepromatous
Non tuberculous mycobacteria
M KANSASII

 Infection of respiratory compromised hosts
Present like pulmonary tuberculosis
Treatment – resistant to anti TB drugs

M SCROFULACEUM

 Infection of cervical lymph nodes
Presents as cervical lymphadenopathy
Treatment – surgery
Non tuberculous mycobacteria
M avium intracellulare Immuno competent host

Infection of cervical lymph nodes
Presents as cervical lymphadenopathy
Treatment – surgery

M avium intracellulare Immuno deficient host

 severe RTI
AIDS severe GI infection
septicaemia
Non tuberculous mycobacteria
M ulcerans

 ‘Buruli’ ulcer
 Prolonged incubation required for growth

M fortuitum / M chelonei

 Injection related abscesses
Associated with sternal wound infections
following cardo-thoracic surgery