| Clostridium novyi | |
|---|---|
Scientific classification 
| |
| Domain: | Bacteria |
| Phylum: | Bacillota |
| Class: | Clostridia |
| Order: | Eubacteriales |
| Family: | Clostridiaceae |
| Genus: | Clostridium |
| Species: |
C. novyi
|
| Binomial name | |
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Clostridium novyi (Migula 1894 [sic]) Bergey et al. 1923
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Clostridium novyi (oedematiens) a Gram-positive, endospore- forming, obligate anaerobic bacteria of the class Clostridia. It is ubiquitous, being found in the soil and faeces. It is pathogenic, causing a wide variety of diseases in man and animals.
Growth in culture proceeds through 3 stages: Initial growth wherein no toxin is produced; vigorous growth wherein toxin is produced; and spore formation wherein endospores are formed and toxin production decreases. It is suggested that type C may be type B that forms spores more readily so does not go through the toxin-production stage.
Isolating and identifying C novyi is difficult due to its extreme anaerobic nature. Commercial kits may not be adequate.
It is also fastidious and difficult to culture, requiring the presence of thiols.
Taxonomy
Clostridium novyi is considered to be made up from three clades, labelled A, B and C, distinguished by the range of toxins they produce. While strains of type C were not linked to disease to laboratory animals, presence and activity of toxins in C. novyi have been linked to infection with Bacteriophages. Based on toxin production, Clostridium haemolyticum has been suggested to be considered a part of C. novyi, forming a separate type D in the genus. More recent 16S-rDNA studies however have suggested, that C. haemolyticus and types B and C of C. novyi may form a distinct genus, closely related to Clostridium botulinum type C and D, instead.
Toxins
- The toxins are designated by Greek letters. The toxins normally produced by the various types are shown in table 1
| Table 1 | |
|---|---|
| C novyi type | Toxins |
| A | alpha, gamma, delta, epsilon |
| B | alpha, beta, zeta |
| C | gamma |
The alpha-toxin of Clostridium botulinum types C and D, is similar to the C novyi beta-toxin. The A and B toxins of Clostridium difficile show homology with the alpha-toxin of C novyi as does the lethal toxin of clostridium sordellii.
Alpha-toxin
The alpha-toxin is characterised as lethal and necrotizing.
The type A alpha-toxin is oedematising. It acts by causing morphological changes to all cell types especially endothelial cells by inhibition of signal transduction pathways, resulting in the breakdown of cytoskeletal structures. The cells of the microvascular system become spherical and the attachments to neighbouring cells are reduced to thin strings. This results in leakage from the capillaries, leading to oedema. The threshold concentration for this action to occur is 5 ng/ml (5 parts per billion) with 50% of cells rounded at 50 ng/ml.
- The duodenum is particularly sensitive to the toxin. Injection into dogs resulted in extreme oedema of the submucosal tissues of the duodenum while leaving the stomach uninjured. Injection into the eye resulted in lesions similar to flame haemorrhages found in diabetic retinopathy.
- The toxin is a large 250-kDa protein the active part of which is the NH2-terminal 551 amino acid fragment. Alpha-toxins are glycosyltransferases, modifying and thereby inactivating different members of the Rho and Ras subfamily of small GTP-binding proteins.C novyi type A alpha-toxin is unique in using UDP-N-acetylglucosamine rather than UDP-glucose as a substrate.
Beta-toxin
The beta-toxin is characterised as haemolytic, necrotizing lecithinase.
Gamma-toxin
The gamma-toxin is characterised as haemolytic, lecithinase.
Delta-toxin
The delta-toxin is characterised as oxygen labile haemolysin.
Epsilon-toxin
The epsilon-toxin is characterised as lecithino-vitelin and thought to be responsible for the pearly layer found in cultures.
Zeta-toxin
The zeta-toxin is characterised as haemolysin.
Human diseases
The type and severity of the disease caused depends on penetration of the tissues. The epithelium of the alimentary tract, in general, provides an effective barrier to penetration. However, spores may escape from the gut and lodge in any part of the body and result in spontaneous infection should local anaerobic conditions occur.
Tissue penetration
Wound infection by C novyi and many other clostridium species cause gas gangrene Spontaneous infection is mostly associated with predisposing factors of hematologic or colorectal malignancies and with diabetes mellitus, although Gram-negative organisms, including Escherichia coli, may lead to a gas gangrene-like syndrome in diabetic patients. This presents with cellulitis and crepitus, and may be mistaken for gas gangrene. Spontaneous, nontraumatic, or intrinsic infections from a bowel source have been increasingly reported recently.
Clostridium novyi has been implicated in mortality among injecting illegal drug users.
Epithelial infections
Symptoms are often non-specific including, colitis, oedematous duodenitis, and fever with somnolence.
Testing is problematical with figures presented by McLauchlin and Brazier [cited above] suggesting a false negative rate of about 40% under ideal conditions. Only positive results may be regarded as reliable. In the absence of a positive test, C. novyi type A may be inferred from characterisation by clinical observation, table 2.
| Table 2 | |
|---|---|
| Observation | Comment |
| Oedema | Especially if extreme with rapid onset. In view of the sensitivity of the duodenum to the alpha-toxin, oedematous duodenum is always suspect. |
| Anaerobic | Infection occurs at an anaerobic site such as the gut or salivary gland. It may also occur at a site temporarily made anaerobic by occlusion and maintained in this state by oedema. |
| Gram positive | If penicillin causes remission of oedema then a Gram positive organism is the causative agent. |
Chronic infection leading to leaky capillaries may also cause retinal haemorrhages and oedema in the lower extremities leading to necrosis and gangrene. Leaky nephrons may compromise the ability of kidneys to concentrate urine leading to frequent urination and dehydration.
Animal diseases
Gas gangrene: infectious necrotic hepatitis (black disease)
See also
- Clostridium novyi-NT, an attenuated form of Clostridium novyi-NT being studied for its potential use as a cancer treatment
Further reading
- Mengesha, Asferd; Dubois, Ludwig; Paesmans, Kim; Wouters, Brad; Lambin, Philippe; Theys, Jan (2009). "Clostridia in Anti-tumour Therapy". In Brüggemann, Holger; Gottschalk, Gerhard (eds.). Clostridia: Molecular Biology in the Post-genomic Era. Norfolk, England: Caister Academic Press. pp. 199–214. ISBN 978-1-904455-38-7.
- Bettegowda C, Dang LH, Abrams R, et al. (December 2003). "Overcoming the hypoxic barrier to radiation therapy with anaerobic bacteria". Proceedings of the National Academy of Sciences of the United States of America. 100 (25): 15083–8. Bibcode:2003PNAS..10015083B. doi:10.1073/pnas.2036598100. PMC 299912. PMID 14657371.
- Groot AJ, Mengesha A, van der Wall E, van Diest PJ, Theys J, Vooijs M (December 2007). "Functional antibodies produced by oncolytic clostridia". Biochemical and Biophysical Research Communications. 364 (4): 985–9. doi:10.1016/j.bbrc.2007.10.126. PMID 17971292.
- Dang LH, Bettegowda C, Huso DL, Kinzler KW, Vogelstein B (December 2001). "Combination bacteriolytic therapy for the treatment of experimental tumors". Proceedings of the National Academy of Sciences of the United States of America. 98 (26): 15155–60. Bibcode:2001PNAS...9815155D. doi:10.1073/pnas.251543698. PMC 64999. PMID 11724950.
- St Jean AT, Zhang M, Forbes NS (October 2008). "Bacterial Therapies: Completing the Cancer Treatment Toolbox". Current Opinion in Biotechnology. 19 (5): 511–7. doi:10.1016/j.copbio.2008.08.004. PMC 2600537. PMID 18760353.