Genus Corynebacterium pdf - د. انسام محمد

Lec-5 Genus Corynebacterium د.انسام محمد

Non spore forming gram positive rods

The genus Corynebacterium comprises 66 species, 38 of them are of clinical significance.

The majority are normal flora on the skin and mucous membrane of human and animals.

They frequently show club-shaped swellings and hence the name Corynebacteria (from

coryne, meaning club).

The term dephtheroid means diphtheria like. The most significant pathogen of the group is

C. diphtheriae. Other spp. are C.bovis, C.ulcerans, C.xerosis, C.jekeium etc.

Corynebacterium diphtheriae

Morphology

They are, thin, gram-positive bacilli, highly pleomorphic, non-motile and non-spore

forming with a tendency to clubbing at one or both ends, arranged in pairs, palisades or

resembling the letters V or L. This particular arrangement is called the Chinese letter

arrangement.

This organism has granular and uneven staining. These granules are known as

metachromatic granules, volutin granules or Babes Ernst granules which are often

situated at the poles of the bacilli and are called polar bodies. Special stain; Albert’s stain

has been used for demonstrating the granules clearly. The granules represent accumulation

of polymerized polyphosphates.

Cultural Characteristics

C. diphtheriae is a facultative anaerobe, It can grow on ordinary nutrient agar. The growth

is improved on enriches media. The media are useful for this purpose:

1. Loeffler’s serum slope 2. Tinsdale agar

3. Tellurite blood agar: The addition of potassium tellurite makes the medium selective for

Corynebacteria by inhibiting most other pathogenic and commensal bacteria. On this

medium, C. diphtheriae give grey/black, shiny or dull colonies.

Based on colonial morphology on the tellurite medium and other properties, there are

four biotypes of C diphtheriae have been widely recognized: gravis, mitis, intermedius,

and belfanti. They are classified on the basis of growth characteristics such as colony

morphology, biochemical reactions, and severity of disease produced by infection.

Toxin

Only toxin producing C. diphtheriae causes the disease diphtheria. Toxigenic strains of C.

diphtheriae produce a very powerful exotoxin. The toxigenicity of the C. diphtheriae

depends on the presence of corynephages (tox+), which act as the genetic determinant

controlling toxin production. Non-toxigenic strains can be converted to tox+ by infection

with the appropriate bacteriophage. This is known as lysogenic or phage conversion.

When some non-toxigenic diphtheria organisms are infected with bacteriophage from

certain toxigenic diphtheria bacilli, the offspring of the exposed bacteria are lysogenic and

toxigenic, and this trait is subsequently hereditary.

The toxin consists of two fragments A (active) and B (binding). Both fragments are required

for toxicity. Fragment A has all the enzymatic activity whereas fragment B is responsible for

binding the toxin to the cells and mediates the entry of fragment A into the cytoplasm. The

toxin is heat labile. It has a special affinity for certain tissues such as the myocardium,

adrenals and nerve endings.

This toxin is very potent and 130ng/Kg is lethal for humans. The production of the toxin in

vitro needs: a. alkaline PH. b. oxygen. c. low iron.

Mode of Action

The diphtheria toxin acts by inhibiting protein synthesis which is responsible for both the

necrotic and neurotoxic effects of the toxin.

The “virulence” of diphtheria bacilli is attributable to their capacity for establishing

infection, growing rapidly, and then quickly elaborating toxin that is effectively absorbed.

Clinical infections

The organism is carried in the upper respiratory tract and spread by droplet infection or

hand-to-mouth contact. The incubation period of diphtheria is 2–5 days. It occurs in two

forms (respiratory and cutaneous) and is found worldwide.

A. Respiratory Diphtheria

The illness begins gradually and is characterized by low-grade fever, malaise, and a mild

sore throat. The most common site of infection is the tonsils or pharynx. The organisms

rapidly multiply on the epithelial cells, and the toxigenic strains of C. diphtheriae produce

toxin locally, causing inflammatory reaction, tissue necrosis and exudate formation

forming a tough gray to white pseudomembrane, which attaches to the tissues commonly

over the tonsils, pharynx, or larynx. Any attempt to remove the pseudomembrane results

in bleeding.

In nasopharyngeal infection, the pseudomembrane may involve nasal mucosa, the

pharyngeal wall and the soft palate. In this form, oedema involving the cervical lymph

glands may occur in the anterior tissues of the neck, a condition known as bull-neck

diphtheria.

Laryngeal involvement leads to obstruction of the larynx and lower airways.

The toxin also is absorbed and can produce a variety of systemic effects involving the

kidneys, heart, and nervous system, although all tissues may be affected.

Intoxication takes the form of myocarditis and peripheral neuritis, and may be associated

with thrombocytopenia. Difficulty in swallowing and paralysis of the arms and legs also

occur but usually resolve spontaneously. Death is most commonly due to congestive heart

failure and cardiac arrhythmias.

B. Cutaneous Diphtheria

It is prevalent in the tropics, the toxin also is absorbed systemically, but systemic

complications are less common than from upper respiratory infections.

Laboratory Diagnosis

Specific treatment should be done immediately on suspicion of diphtheria without waiting

for laboratory tests. Any delay may be fatal. Laboratory diagnosis consists of isolation of

the diphtheria bacillus and demonstration of its toxicity.

1. Specimens

Swabs from the nose, throat, or other suspected lesions must be obtained before

antimicrobial drugs are administered.

2. Microscopy

Direct microscopy of a smear is unreliable since C. diphtheriae is morphologically similar to

other coryneforms. Stained smears show beaded rods in typical arrangement.

3. Culture

The swab should be inoculated on Loffler’s serum slope, tellurite blood agar, and blood

agar. The cultures should be incubated aerobically at 37°C.

4. Virulence Tests

To test for toxigenicity of an isolated diphtheria. Diagnosis of diphtheria

depends on showing that the isolate produces diphtheria toxin.

A. In vivo tests

i. Subcutaneous test: The growth from an overnight culture on Loeffler’s slope is

emulsified in 2–4 ml broth and 1 ml of the emulsion injected subcutaneously into two

guinea pigs or rabbits, one of which has been protected with the diphtheria antitoxin (500–

1000 units) 18–24 hours previously and was used as control. If the strain is virulent, the

unprotected animal will die within four days.

ii. Intracutaneous test no loss of the animal.

B. In vitro Test

i. Elek’s gel precipitation test: The in vitro diphtheria toxin detection procedure is an

immunodiffusion test first described by Elek.

Procedure: A rectangular strip of filter paper impregnated with diphtheria antitoxin (1000

units/ ml) is placed on the surface of a 20% normal horse serum agar in a Petri dish while

the medium is still fluid. When the agar has set, the surface is dried. The plate should be

streaked with the test strain as well as the control positive and negative strains at right

angles to the strip in a single straight line and parallel to each other. The plate is incubated

at 37°C and examined after 24 and 48 hours.

Interpretation: Toxins produced by the bacterial growth will diffuse in the agar and where

it meets the antitoxin at optimum concentration will produce a line of precipitation. A

negative control should be free of any line. No precipitate will form in the case of non-

toxigenic strains.

ii. Tissue culture test: The toxigenicity of diphtheria bacilli can be demonstrated by

incorporating the strains in the agar overlay of cell culture monolayers. The toxin produced

diffuses into the cells below and kills them.

iii. Enzyme-linked immunosorbent assays (ELISA): are available for the detection of

diphtheria toxin.

iv. Polymerase chain reaction (PCR): for detecting the C. diphtheriae tox gene. The PCR

assay can also be applied directly to clinical specimens.

Prophylaxis

The methods of immunization available are active, passive or combined.

A. Active Immunization

1. Single vaccines are less frequently used

2. Combined preparations:

– DPT (diphtheria-pertussis-tetanus) vaccine trivalent preparation

B. Passive Immunization

This is an emergency measure to be employed where susceptible (non-immunized) are

exposed to infection. It consists of the subcutaneous administration of 500–1000 units of

antitoxin (antidiphtheritic serum, ADS).

Treatment

Specific treatment of diphtheria consists of antitoxic and antibiotic therapy. Antitoxin

should be given immediately as soon as clinical diagnosis is made to neutralize the toxin

being produced. The dosage recommended is 20,000 units intramuscularly for moderate

cases and 50,000 to 100,000 units for serious cases, half the dose being given intravenously.

C. diphtheriae is sensitive to most antibiotics, including penicillin and erythromycin for the

treatment of patients as well as carriers. The antibiotics do not neutralize circulating toxin.

Penicillin-sensitive individuals can be given erythromycin. Erythromycin is more active than

penicillin in the treatment of carriers.

Diphtheroids

Corynebacteria resembling C. diphtheriae occur as normal commensals in the throat, skin

and other areas. These may be mistaken for diphtheria bacilli and are known as

diphtheroids. They can be differentiated from C. diphtheria on the basis of biochemical

characters and toxigenicity tests. The common diphtheroids are C. pseudodiphtheriticum

and C. xerosis.

Listeria monocytogenes

L.monocytogenes is an important human pathogen, wide spread in the environment

recovered from soil, water, and animal products. It has tropism to the CNS. L

monocytogenes is capable of growing and surviving over a wide range of environmental

conditions. It can survive at refrigerator temperatures (4°C), under conditions of low pH

and high salt conditions. Therefore, it is able to overcome food preservation and safety

barriers, making it an important food-borne pathogen. It

secretes

Listeriolysin O which

damages the phagosome membrane and inhibit killing by macrophages

Clinical infections

Pregnant women: flulike illness with fever head ache and myalgia, seen mostly in the

third trimester. It may cause premature labor, septic abortion within 3-7 days, spontaneous

abortion and stillborn neonates. The infection usually self limited.

Newborn: causes serious infections. Early onset associated with aspiration of

infected amniotic fluid and have high mortality rate. Late onset disease occurs several days

or weeks after birth with lower fatality rate. The disease manifest as meningitis.

Immunosuppressed host: invasive listeriosis causing CNS infection with high fatality

rate.

Healthy people: cause GIT infection when they eat food contaminated with the MO.

Laboratory diagnosis

Microscopically: gram positive coccobacilli, singly, short chains or palisades.

Culture: grow on SBA and chocolate agar as well as nutrient agar. The colonies are small

round smooth and translucent surrounded by narrow zone of beta hemolysis. The MO

grows at 4C° so cold enrichment is used to isolate the MO using broth incubated at 4C° for

several weeks.

Identification: catalase positive, motile, beta hemolytic, CAMP test positive.

References

Koneman's color atlas and textbook of diagnostic microbiology 7

edition, 2017.

Bailey and Scott's Diagnostic Microbiology 14

edition, 2017.

Jawetz, Melnick and Adelberg's medical microbiology 26

edition, 2013.