Corynebacterium diphtheriae

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Corynebacterium diphtheriae
Corynebacterium diphtheriae Gram stain.jpg
Scientific classification
Domain:
Bacteria
Phylum:
"Actinobacteria"
Class:
Actinobacteria
Order:
Mycobacteriales
Family:
Corynebacteriaceae
Genus:
Corynebacterium
Species:
C. diphtheriae
Binomial name
Corynebacterium diphtheriae
(Kruse 1886) Lehmann and Neumann 1896[1]

Corynebacterium diphtheriae[a] is the pathogenic bacterium that causes diphtheria.[2] It is also known as the Klebs–Löffler bacillus, because it was discovered in 1884 by German bacteriologists Edwin Klebs (1834–1912) and Friedrich Löffler (1852–1915).

Classification[]

Four subspecies are recognized: C. d. mitis, C. d. intermedius, C. d. gravis, and C. d. belfanti. The four subspecies differ slightly in their colonial morphology and biochemical properties, such as the ability to metabolize certain nutrients, but all may be toxigenic (and therefore cause diphtheria) or not toxigenic. C. diphtheriae produces diphtheria toxin which alters protein function in the host by inactivating the elongation factor EF-2. This causes pharyngitis and 'pseudomembrane' in the throat. The diphtheria toxin gene is encoded by a bacteriophage found in toxigenic strains, integrated into the bacterial chromosome.[3][4]

To accurately identify C. diphtheriae, a Gram stain is performed to show Gram-positive, highly pleomorphic organisms with no particular arrangement. Special stains like and are used to demonstrate the metachromatic granules formed in the polar regions. The granules are called polar granules, Babes Ernst granules, volutin granules etc. An enrichment medium, such as Löffler's medium, is used to preferentially grow C. diphtheriae. After that, a differential plate known as tellurite agar, allows all Corynebacteria (including C. diphtheriae) to reduce tellurite to metallic tellurium. The tellurite reduction is colorimetrically indicated by brown colonies for most Cornyebacterium species or by a black halo around the C. diphtheriae colonies.

A low concentration of iron is required in the medium for toxin production. At high iron concentrations, iron molecules bind to an aporepressor on the beta bacteriophage, which carries the Tox gene. When bound to iron, the aporepressor shuts down toxin production.[5] Elek's test for toxigenicity is used to determine whether the organism is able to produce the diphtheria toxin.

Pathogen and disease[]

A diphtheria lesion on the leg

Corynebacterium diphtheriae is the bacterium that causes the disease diphtheria. C. diphtheriae is a rod-shaped, Gram-positive, nonspore-forming, and nonmotile bacterium.[6] The disease occurs primarily in tropical regions and underdeveloped countries, but has been known to appear throughout the world. Immunocompromised individuals, poorly immunized adults, and unvaccinated children are at the greatest risk for contracting diphtheria. During the typical course of disease, the only affected body region is the upper respiratory system. A thick, gray coating accumulates in the nasopharyngeal region, making breathing and swallowing more difficult. The disease remains contagious for at least two weeks following disappearance of symptoms, but has been known to last for up to a month.[7] The most common routes of entry for C. diphtheriae are the nose, tonsils, and throat. Individuals suffering from the disease may experience sore throat, weakness, fever, and swollen glands. Mode of transmission is person-to-person contact via respiratory droplets (i.e., coughing or sneezing), and less commonly, by touching open sores or contaminated surfaces. If left untreated, diphtheria toxin may enter the bloodstream, causing damage to the kidneys, nerves, and heart. Extremely rare complications include suffocation and partial paralysis. A vaccine, DTap, effectively prevents the disease and is mandatory in the United States for participation in public education and some professions (exceptions apply).

Pathogenesis[]

In areas where diphtheria is endemic, C. diphtheriae in the nasopharyngeal passageways is common. Its exotoxin is absorbed in the blood, which in turn kills heart, kidney, and nerve cells by blocking protein synthesis.[8] Toxigenic strains in susceptible individuals can cause disease by multiplying and secreting diphtheria toxin into either skin or nasopharyngeal lesions. The diphtheritic lesion is often covered by a pseudomembrane composed of fibrin, bacterial cells, and inflammatory cells. Diphtheria toxin can be proteolytically cleaved into two fragments - an N-terminal fragment A (catalytic domain), and fragment B (transmembrane and receptor binding domain). Fragment A catalyzes the NAD+ -dependent ADP-ribosylation of elongation factor 2, thereby inhibiting protein synthesis in eukaryotic cells. Fragment B binds to the cell surface receptor and facilitates the delivery of fragment A to the cytosol.

Sensitivity[]

The bacterium is sensitive to the majority of antibiotics, such as the penicillins, ampicillin, cephalosporins, quinolones, chloramphenicol, tetracyclines, cefuroxime, and trimethoprim[citation needed].

Genetics[]

The genome of C. diphtheriae consists of a single circular chromosome of 2.5 Mbp, with no plasmids.[9][10] The genome shows an extreme compositional bias, being noticeably higher in G+C near the origin than at the terminus.

See also[]

  • Cutaneous diphtheria

Notes[]

  1. ^ Pronunciation: /kɔːˈrnəbæktɪəriəm dɪfˈθɪərii, -rɪnə-/.

References[]

  1. ^ Parte, A.C. "Corynebacterium". LPSN.
  2. ^ Hoskisson, P.A. (2018). "Microbe Profile: Corynebacterium diphtheriae – an old foe always ready to seize opportunity" (PDF). Microbiology. 164 (6): 865–867. doi:10.1099/mic.0.000627. PMC 6097034. PMID 29465341.
  3. ^ Freeman, Victor J (1951). "Studies on the Virulence of Bacteriophage-Infected Strains of Corynebacterium Diphtheriae". Journal of Bacteriology. 61 (6): 675–688. doi:10.1128/JB.61.6.675-688.1951. PMC 386063. PMID 14850426.
  4. ^ Freeman VJ, Morse IU; Morse (1953). "Further Observations on the Change to Virulence of Bacteriophage-Infected Avirulent Strains of Corynebacterium Diphtheriae". Journal of Bacteriology. 63 (3): 407–414. doi:10.1128/JB.63.3.407-414.1952. PMC 169283. PMID 14927573.
  5. ^ Nester, Eugene W.; et al. (2004). Microbiology: A Human Perspective (Fourth ed.). Boston: McGraw-Hill. ISBN 0-07-247382-7.
  6. ^ "Diphtheria Infection | Home | CDC". www.cdc.gov. 2017-04-10. Retrieved 2017-11-27.
  7. ^ "Diphtheria | MedlinePlus". Retrieved 2017-11-27.
  8. ^ "Diphtheria". Healthline. Retrieved 2017-11-27.
  9. ^ Cerdeño-Tárraga, A. M.; Efstratiou, A; Dover, L. G.; Holden, M. T.; Pallen, M; Bentley, S. D.; Besra, G. S.; Churcher, C; James, K. D.; De Zoysa, A; Chillingworth, T; Cronin, A; Dowd, L; Feltwell, T; Hamlin, N; Holroyd, S; Jagels, K; Moule, S; Quail, M. A.; Rabbinowitsch, E; Rutherford, K. M.; Thomson, N. R.; Unwin, L; Whitehead, S; Barrell, B. G.; Parkhill, J (2003). "The complete genome sequence and analysis of Corynebacterium diphtheriae NCTC13129". Nucleic Acids Research. 31 (22): 6516–23. doi:10.1093/nar/gkg874. PMC 275568. PMID 14602910.
  10. ^ Sangal, V; Tucker, N. P.; Burkovski, A; Hoskisson, P. A. (2012). "The draft genome sequence of Corynebacterium diphtheriae bv. Mitis NCTC 3529 reveals significant diversity between the primary disease-causing biovars". Journal of Bacteriology. 194 (12): 3269. doi:10.1128/JB.00503-12. PMC 3370853. PMID 22628502.

External links[]

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