Pleomorphism (microbiology)

In microbiology, pleomorphism (from Ancient Greek πλέω-, pléō, "more", and -μορφή, morphḗ, form) is the ability of some microorganisms to alter their morphology, biological functions or reproductive modes in response to environmental conditions. Pleomorphism has been observed in some members of the Deinococcaceae family of bacteria.[1] The modern definition of pleomorphism in the context of bacteriology is based on variation of morphology or functional methods of the individual cell, rather than a heritable change of these characters as previously believed.[1]

Bacteria

In the first decades of the 20th century, the term "pleomorphism" was used to refer to the idea that bacteria change morphology, biological systems, or reproductive methods dramatically according to environmental cues. This claim was controversial among microbiologists of the time, and split them into two schools: the monomorphists, who opposed the claim, and the pleomorphists such as Antoine Béchamp, Ernst Almquist, Günther Enderlein, Albert Calmette,[2] Gastons Naessens, Royal Raymond Rife, and Lida Mattman, who supported the posit. According to a 1997 journal article by Milton Wainwright, a British microbiologist, pleomorphism of bacteria lacked wide acceptance among modern microbiologists of the time.[3]

Helicobacter pylori in curved rod form

Monomorphic theory, supported by Louis Pasteur, Rudolf Virchow, Ferdinand Cohn, and Robert Koch, emerged to become the dominant paradigm in modern medical science: it is now almost universally accepted that each bacterial cell is derived from a previously existing cell of practically the same size and shape. However it has recently been shown that certain bacteria are capable of dramatically changing shape.

Sergei Winogradsky took a middle-ground stance in the pleomorphism controversy. He agreed with the monomorphic school of thought, but disagreed with some of the foundational microbiological beliefs that the prominent monomorphists Cohn and Koch held.[4] Winogradsky published a literature review titled "The Doctrine of Pleomorphism in Bacteriology" in which he attempted to explicate the pleomorphic debate, identifying the fundamental errors within each side's argument.[5] Winogradsky posited that pleomorphists Naegli and Zopf were unable to perceive the existence of bacterial morphological classes, and that Cohn and Koch, within their own suppositions, ignore species of morphologically variant bacteria that are unable to grow within axenic cultures.[5] Winogradsky explained the perception of pleomorphic bacteria as bacteria progressing through different stages within a developmental cycle, thereby providing the fundamental structure for a theory of morphology based upon the concept of dynamic deviation from a morphological type, or biotype.

Coxiella burnetii bacteria displaying pleomorphism

While the pleomorphic debate still exists in its original form to some extent, it has predominantly been altered to a discussion regarding the methods, evolutionary inception, and practical applications of pleomorphism.[6] Many modern scientists regard pleomorphism as either a bacterium's response to pressure exerted by environmental factors, such as bacteria that shed antigenic markers in the presence of antibiotics, or as an occurrence in which bacteria evolve successively more complicated forms.[6] A hypothesis referred to as "Pleomorphic Provolution", a component of Stuart Grace's "Ambimorphic Paradigm", takes both of these theories into consideration.[6]

Although it has recently been shown that certain bacteria are capable of dramatically changing shape, pleomorphy remains a controversial concept. A well accepted example of pleomorphism is Helicobacter pylori, which exists as both a helix-shaped form (classified as a curved rod) and a coccoid form.[7] Legionella pneumophila, the species of intracellular bacteria parasite responsible for Legionnaire's disease, has been seen to differentiate within a developmentally diverse network.[8] The genera Corynebacterium[9] and Coccobacillus[10] have been designated as a pleomorphic genera, diphtheroid Bacilli have been classified as pleomorphic nosocomial bacteria.[11] Additionally, in one study focused on agents involved in a non-infectious disease, pleomorphic bacteria were found to exist in the blood of healthy human subjects.[12]

One factor that affects the pleomorphism of some bacteria is their nutrition. For example, the bacterium Deinococcus radiodurans has been shown to exhibit pleomorphism in relation to differences in the nutrient contents of its environment.[1]

Viruses

The virions of certain viruses sometimes exhibit pleomorphism, in the sense that their appearances can vary. However, this is not true pleomorphism, as individual virions are not changing shape, but being succeeded by virions with different shapes. One example is the bacterial viruses of the Plasmaviridae family.[13] A group of haloarchaeal viruses has been shown to exhibit pleomorphism as well.[14]

References

  1. Joshi HM, Toleti RS (2009). "Nutrition induced pleomorphism and budding mode of reproduction in Deinococcus radiodurans". BMC Research Notes. 2: 123. doi:10.1186/1756-0500-2-123. PMC 2714317. PMID 19583846.
  2. Feldberg, Georgina (1995). Disease and class: tuberculosis and the shaping of modern North American society. Rutgers University Press. ISBN 978-0-8135-2218-0.
  3. Wainwright, M. (1997). "Extreme Pleomorphism and the Bacterial Life Cycle: A Forgotten Controversy". Perspectives in Biology and Medicine. 40 (3): 407–414. doi:10.1353/pbm.1997.0038. S2CID 84781739.
  4. Penn, M Dworkin, M (June 1976). Robert Koch and two visions of microbiology. OCLC 679603238.{{cite book}}: CS1 maint: multiple names: authors list (link)
  5. WINOGRADSKY, S. (May 1937). "The Doctrine of Pleomorphism in Bacteriology". Soil Science. 43 (5): 327–340. Bibcode:1937SoilS..43..327W. doi:10.1097/00010694-193705000-00001. ISSN 0038-075X. S2CID 95249188.
  6. Grace, Stuart (2001). "The Theory of Pleomorphic Provolution: Revisiting the Heresy of Spontaneous Generation" (PDF). Natural Philosophy Research Group.
  7. Andersen, Leif Percival; Rasmussen, Lone (July 2009). "Helicobacter pylori-coccoid forms and biofilm formation". FEMS Immunology & Medical Microbiology. 56 (2): 112–115. doi:10.1111/j.1574-695x.2009.00556.x. ISSN 0928-8244. PMID 19453756.
  8. Robertson, Peter; Abdelhady, Hany; Garduño, Rafael A. (2014-12-22). "The many forms of a pleomorphic bacterial pathogenâ€"the developmental network of Legionella pneumophila". Frontiers in Microbiology. 5: 670. doi:10.3389/fmicb.2014.00670. ISSN 1664-302X. PMC 4273665. PMID 25566200.
  9. Coyle, M B; Lipsky, B A (July 1990). "Coryneform bacteria in infectious diseases: clinical and laboratory aspects". Clinical Microbiology Reviews. 3 (3): 227–246. doi:10.1128/cmr.3.3.227. ISSN 0893-8512. PMC 358157. PMID 2116939.
  10. Rosenthal, Ken S.; Tan, Michael J. (2011), "Gram-Negative Cocci and Coccobacilli", Rapid Review Microbiology and Immunology, Elsevier, pp. 85–89, doi:10.1016/b978-0-323-06938-0.00012-8, ISBN 978-0-323-06938-0
  11. Chandra, Reshmi (2016). "Diphtheroids-Important Nosocomial Pathogens". Journal of Clinical and Diagnostic Research. 10 (12): DC28–DC31. doi:10.7860/jcdr/2016/19098.9043. ISSN 2249-782X. PMC 5296432. PMID 28208859.
  12. McLaughlin, Richard W. Vali, Hojatollah Lau, Peter C. K. Palfree, Roger G. E. De Ciccio, Angela Sirois, Marc Ahmad, Darakhshan Villemur, Richard Desrosiers, Marcel Chan, Eddie C. S. Are There Naturally Occurring Pleomorphic Bacteria in the Blood of Healthy Humans?. American Society for Microbiology. OCLC 679258190.{{cite book}}: CS1 maint: multiple names: authors list (link)
  13. Desk Encyclopedia of General Virology. Boston: Academic Press. 2009. p. 254. ISBN 978-0-12-375146-1.
  14. Senčilo, Ana; Paulin, Lars; Kellner, Stefanie; Helm, Mark; Roine, Elina (2012-03-06). "Related haloarchaeal pleomorphic viruses contain different genome types". Nucleic Acids Research. 40 (12): 5523–5534. doi:10.1093/nar/gks215. ISSN 1362-4962. PMC 3384331. PMID 22396526.
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