Treponema pallidum
Treponema pallidum | |
---|---|
Scientific classification | |
Domain: | Bacteria |
Phylum: | Spirochaetota |
Class: | Spirochaetia |
Order: | Spirochaetales |
Family: | Treponemataceae |
Genus: | Treponema |
Species: | T. pallidum
|
Binomial name | |
Treponema pallidum |
Treponema pallidum is a spirochaete bacterium with various subspecies that cause the diseases syphilis, bejel (also known as endemic syphilis), and yaws. It is chiefly transmitted amongst humans, but it can also cause a condition found in cattle, bovine digital dermatitis.[1][2] It is a helically coiled microorganism usually 6–15 μm long and 0.1–0.2 μm wide.[3] T. pallidum's lack of either a tricarboxylic acid cycle or oxidative phosphorylation results in minimal metabolic activity.[4] The treponemes have a cytoplasmic and an outer membrane. Using light microscopy, treponemes are visible only by using dark field illumination. Treponema pallidum consists of three subspecies, T. p. pallidum, T. p. endemicum, and T. p. pertenue, each of which has a distinct associated disease.[5]
Subspecies
Three subspecies of T. pallidum are known:[6]
- Treponema pallidum pallidum, which causes syphilis
- T. p. endemicum, which causes bejel or endemic syphilis
- T. p. pertenue, which causes yaws
The three subspecies causing yaws, bejel, and syphilis are morphologically and serologically indistinguishable.[3] These bacteria were originally classified as members of separate species, but DNA hybridization analysis indicates they are members of the same species. Treponema carateum, the cause of pinta, remains a separate species because no isolate is available for DNA analysis.[7] Disease transmittance in subspecies T. p. endemicum and T. p. pertenue is considered non-venereal.[8] T. p. pallidum is the most invasive pathogenic subspecies while T. p. carateum is the least invasive of the subspecies. T. p. endemicum and T. p. pertenue are intermediately invasive.[9]
Microbiology
Ultrastructure
Treponema pallidum is a helically shaped bacterium consisting of an outer membrane, peptidoglycan layer, inner membrane, protoplasmic cylinder, and periplasmic space.[citation needed] It is often described as Gram negative, but its outer membrane lacks lipopolysaccharide, which is found in the outer membrane of other Gram-negative bacteria.[10] It has an endoflagella (periplasmic flagella) consisting of four main polypeptides, a core structure, and a sheath.[citation needed] The flagella is located within the periplasmic space and wraps around the protoplasmic cylinder. T. pallidum's outer membrane has the most contact with host cells and contains few transmembrane proteins, limiting antigenicity while its cytoplasmic membrane is covered in lipoproteins.[4][11] The outer membrane's treponemal ligands main function is attachment to host cells, with functional and antigenic relatedness between ligands.[12] The genus Treponema has ribbons of cytoskeletal cytoplasmic filaments that run the length of the cell just underneath the cytoplasmic membrane. They are composed of the intermediate filament-like protein CfpA (cytoplasmic filament protein A). Although the filaments may be involved in chromosome structure and segregation or cell division, their precise function is unknown.[13][11]
Culture
Successful long-term cultivation of T. pallidum subspecies pallidum in a tissue culture system has been reported in 2018.[14]
However, because T. pallidum cannot be grown in a pure culture, it does not satisfy Koch's Postulates.[15]
Genome
The chromosomes of the T. pallidum subspecies are small, about 1.14 Mbp. Their DNA sequences are more than 99.7% identical.[16] T. pallidum subspecies pallidum was sequenced in 1998.[17] This sequencing is significant due to T. pallidum not being capable of growing in a pure culture, meaning that this sequencing played an important role in understanding the microbe's functions. It revealed that T. pallidum relies on its host for many molecules provided by biosynthetic pathways, and that it is missing genes responsible for encoding key enzymes in oxidative phosphorylation and the tricarboxylic acid cycle. It was found that this is due to 5% of T. pallidum's genes coding for transport genes.[18] The recent sequencing of the genomes of several spirochetes permits a thorough analysis of the similarities and differences within this bacterial phylum and within the species.[19][20][21] T. p. pallidum has one of the smallest bacterial genomes at 1.14 million base pairs, and has limited metabolic capabilities, reflecting its adaptation through genome reduction to the rich environment of mammalian tissue. The shape of T. pallidum is flat and wavy.[22] In order to avoid antibodies attacking, the cell has few proteins exposed on the outer membrane sheath.[23] Its chromosome of about 1000 kilo base pairs is circular with a 52.8% G + C average.[24] Sequencing has revealed a bundle of twelve proteins and some putative hemolysins are potential virulence factors of T. pallidum.[25] 92.9% of DNA was determined to be ORF's, 55% of which had predicted biological functions.[4]
Clinical significance
The clinical features of syphilis, yaws, and bejel occur in multiple stages that affect the skin. The skin lesions observed in the early stage last for weeks or months. The skin lesions are highly infectious, and the spirochetes in the lesions are transmitted by direct contact. The lesions regress as the immune response develops against T. pallidum. The latent stage that results lasts a lifetime in many cases. In a minority of cases, the disease exits latency and enters a tertiary phase, in which destructive lesions of skin, bone, and cartilage ensue. Unlike yaws and bejels, syphilis in its tertiary stage often affects the heart, eyes, and nervous system as well.[7]
Syphilis
Treponema pallidum pallidum is a motile spirochaete that is generally acquired by close sexual contact, entering the host via breaches in squamous or columnar epithelium. The organism can also be transmitted to a fetus by transplacental passage during the later stages of pregnancy, giving rise to congenital syphilis. The helical structure of T. p. pallidum allows it to move in a corkscrew motion through mucous membranes or enter minuscule breaks in the skin. In women the initial lesion is usually on the labia, the walls of the vagina, or the cervix; in men it is on the shaft or glans of the penis.[3] It gains access to the host's blood and lymph systems through tissue and mucous membranes. In more severe cases, it may gain access to the host by infecting the skeletal bones and central nervous system of the body.[3]
The incubation period for a T. p. pallidum infection is usually around 21 days, but can range from 10 to 90 days.[26]
Laboratory identification
Treponema pallidum was first microscopically identified in syphilitic chancres by Fritz Schaudinn and Erich Hoffmann at the Charité in Berlin in 1905.[27] This bacterium can be detected with special stains, such as the Dieterle stain. T. pallidum is also detected by serology, including nontreponemal VDRL, rapid plasma reagin, treponemal antibody tests (FTA-ABS), T. pallidum immobilization reaction, and syphilis TPHA test.[28]
Treatment
During the early 1940s, rabbit models in combination with the drug penicillin allowed for a long term drug treatment. These experiments establish the ground work that modern scientists use for syphilis therapy. Penicillin can inhibit T. pallidum in 6–8 hours though the cells still remain in lymph nodes and regenerate. Penicillin is not the only drug that can be used to inhibit T. pallidum; it has been found that any β-lactam antibiotics or macrolides can be used.[29] The T. pallidum strain 14 has built resistance to some macrolides, including erythromycin and azithromycin. Resistance to macrolides in T. Pallidum strain 14 is believed to derive from a single point mutation that increased the organism's livability.[30] Many of the syphilis treatment therapies only lead to bacteriostatic results, unless larger concentrations of penicillin are used for bactericidal effects.[29][30] Penicillin overall is the most recommended antibiotic by the CDC as it shows the best results with prolonged usage. It can inhibit and may even kill T. Pallidum at low to high doses with each increase in concentration being more effective.[30]
Vaccine
No vaccine for syphilis is available as of 2017. The outer membrane of T. pallidum has too few surface proteins for an antibody to be effective. Efforts to develop a safe and effective syphilis vaccine have been hindered by uncertainty about the relative importance of humoral and cellular mechanisms to protective immunity,[31] and because T. pallidum outer membrane proteins have not been unambiguously identified.[32][33] In contrast, some of the known antigens are intracellular, and antibodies are ineffective against them to clear the infection.[34][35][36]
References
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- ^ a b c Norris, Cox, Weinstock, Steven J., David L., George M. (2001). "Biology of Treponema pallidum: Correlation of Functional Activities With Genome Sequence Data" (PDF). JMMB Review. 3 (1): 37–62. PMID 11200228 – via https://www.caister.com/backlist/jmmb/v/v3/v3n1/03.pdf.
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- ^ Centurion-Lara, Arturo; Molini, Barbara J.; Godornes, Charmie; Sun, Eileen; Hevner, Karin; Voorhis, Wesley C. Van; Lukehart, Sheila A. (1 September 2006). "Molecular Differentiation of Treponema pallidum Subspecies". Journal of Clinical Microbiology. 44 (9): 3377–3380. doi:10.1128/JCM.00784-06. ISSN 0095-1137. PMC 1594706. PMID 16954278.
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Further reading
- Althouse BM, Hébert-Dufresne L (October 2014). "Epidemic cycles driven by host behaviour". Journal of the Royal Society, Interface. 11 (99): 20140575. doi:10.1098/rsif.2014.0575. PMC 4235258. PMID 25100316.
External links
- "Syphilis- CDC Fact Sheet." Centers for Disease Control and Prevention. May. 2004. Centers for Disease Control and Prevention. 7 February 2006