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Trypanosoma cruzi

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Trypanosoma cruzi
Trypanosoma cruzi in human blood Giemsa stain. They are typically seen as a C-shape and have a more pronounced kinetoplast compared to other species.
Scientific classification Edit this classification
Domain: Eukaryota
Phylum: Euglenozoa
Class: Kinetoplastea
Order: Trypanosomatida
Family: Trypanosomatidae
Genus: Trypanosoma
Species:
T. cruzi
Binomial name
Trypanosoma cruzi

Trypanosoma cruzi is a species of parasitic euglenoids. Among the protozoa, the trypanosomes characteristically bore tissue in another organism and feed on blood (primarily) and also lymph. This behaviour causes disease or the likelihood of disease that varies with the organism: Chagas disease in humans, dourine and surra in horses, and a brucellosis-like disease in cattle. Parasites need a host body and the haematophagous insect triatomine (descriptions "assassin bug", "cone-nose bug", and "kissing bug") is the major vector in accord with a mechanism of infection. The triatomine likes the nests of vertebrate animals for shelter, where it bites and sucks blood for food. Individual triatomines infected with protozoa from other contact with animals transmit trypanosomes when the triatomine deposits its faeces on the host's skin surface and then bites. Penetration of the infected faeces is further facilitated by the scratching of the bite area by the human or animal host.

Etymology

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The specific name "cruzi" is an honor to Brazilian scientist Oswaldo Cruz, who taught discoverer Carlos Chagas.[4]

Life cycle

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The Trypanosoma cruzi life cycle starts in an animal reservoir, usually mammals, wild or domestic, including humans. A triatomine bug serves as the vector. While taking a blood meal, it ingests T. cruzi. In the triatomine bug (the principal species of which in terms of parasite transmission to humans being Triatoma infestans) the parasite goes into the epimastigote stage, making it possible to reproduce. After reproducing through binary fission, the epimastigotes move onto the rectal cell wall, where they become infectious. Infectious T. cruzi are called metacyclic trypomastigotes. When the triatomine bug subsequently takes a blood meal from a host, it defecates—its waste containing T. cruzi propagation stages. As a result, Trumper and Gorla 1991 find transmission success centers around the triatomine's defecation behaviors.[5][6][7] Alternatively, in nature and in most recent cases of epidemiological outbreaks, infection occurs through the oral ingestion of parasites (mainly through a lack of infected food disinfection in the case of human infection). [8][9] The trypomastigotes are in the feces and are capable of swimming into the host's cells using flagella, a characteristic swimming tail dominant in the Euglenoid class of protists.[10] The trypomastigotes enter the host through the bite wound or by crossing mucous membranes. The host cells contain macromolecules such as laminin, thrombospondin, heparin sulphate, and fibronectin that cover their surface.[11] These macromolecules are essential for adhesion between parasite and host and for the process of host invasion by the parasite. The trypomastigotes must cross a network of proteins that line the exterior of the host cells in order to make contact and invade the host cells. The molecules and proteins on the cytoskeleton of the cell also bind to the surface of the parasite and initiate host invasion.[11]

Pathophysiology

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Trypanosomiasis in humans progresses with the development of the trypanosome into a trypomastigote in the blood and into an amastigote in tissues. As the infection progresses, the number of infected cells increases, as well as the number of amastigotes per infected cell (APC). If the average of APC is one or close to one, the infection has just begun. A higher APC means that amastigotes have started to replicate.[12]

The acute form of trypanosomiasis is usually unnoticed, although it may manifest itself as a localized swelling at the site of entry. In this form appears elevated parasitism, myocarditis, and changes in the myocardial gene expression. The chronic form may develop 30 to 40 years after infection and affect internal organs (e.g., the heart, the oesophagus, the colon, and the peripheral nervous system). Affected people may die from heart failure and severe heart lesions.[13]

Acute cases are treated with nifurtimox and benznidazole, but no effective therapy for chronic cases is currently known.[citation needed]

Cardiac manifestations

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Researchers of Chagas’ disease have demonstrated several processes that occur with all cardiomyopathies. The first event is an inflammatory response. Following inflammation, cellular damage occurs. Finally, in the body's attempt to recover from the cellular damage, fibrosis begins in the cardiac tissue.[14]

Another cardiomyopathy found in nearly all cases of chronic Chagas’ disease is thromboembolic syndrome. Thromboembolism describes thrombosis, the formation of a clot, and its main complication is embolism, the carrying of a clot to a distal section of a vessel and causing blockage there. This occurrence contributes to the death of a patient by four means: arrhythmias, stasis secondary to cardiac dilation, mural endocarditis, and cardiac fibrosis. These thrombi also affect other organs such as the brain, spleen and kidney.[15]

Myocardial biochemical response

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Subcellular findings in murine studies with induced T. cruzi infection revealed that the chronic state is associated with the persistent elevation of phosphorylated (activated) extracellular-signal-regulated kinase (ERK), AP-1, and NF-κB. Also, the mitotic regulator for G1 progression, cyclin D1 was found to be activated. Although there was no increase in any isoform of ERK, there was an increased concentration of phosphorylated ERK in mice infected with T. cruzi. It was found that within seven days the concentration of AP-1 was significantly higher in T. cruzi–infected mice when compared to the control. Elevated levels of NF-κB have also been found in myocardial tissue, with the highest concentrations being found in the vasculature. It was indicated through Western blot that cyclin D1 was upregulated from day 1 to day 60 post-infection. It was also indicated through immunohistochemical analysis that the areas that produced the most cyclin D1 were the vasculature and interstitial regions of the heart.[16]

Rhythm abnormalities

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Conduction abnormalities are also associated with T. cruzi. At the base of these conduction abnormalities is a depopulation of parasympathetic neuronal endings on the heart. Without proper parasympathetic innervations, one could expect to find not only chronotropic but also inotropic abnormalities. It is true that all inflammatory and non-inflammatory heart disease may display forms of parasympathetic denervation; this denervation presents in a descriptive fashion in Chagas’ disease. It has also been indicated that the loss of parasympathetic innervations can lead to sudden death due to a severe cardiac failure that occurs during the acute stage of infection.[17]

Another conduction abnormality presented with chronic Chagas’ disease is a change in ventricular repolarization, which is represented on an electrocardiogram as the T-wave. This change in repolarization inhibits the heart from relaxing and properly entering diastole. Changes in the ventricular repolarization in Chagas’ disease are likely due to myocardial ischemia. This ischemia can also lead to fibrillation. This sign is usually observed in chronic Chagas’ disease and is considered a minor electromyocardiopathy.[18]

Epicardial lesions

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Villous plaque is characterized by exophytic epicardial thickening, meaning that the growth occurs at the border of the epicardium and not the center of mass. Unlike milk spots and chagasic rosary, inflammatory cells and vasculature are present in villous plaque. Since villous plaque contains inflammatory cells it is reasonable to suspect that these lesions are more recently formed than milk spots or chagasic rosary.[19]

Motility

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When mammalian cells are present, trypomastigotes move in a sub diffusive fashion in short periods of time, but under control conditions their motion is diffusive.

Parasites increase their mean speed; they explore smaller areas at short time scales and show a preference to be located nearby cells’ periphery. The extent of these changes depends on the cell type. Therefore, T. cruzi trypomastigotes can sense mammalian cells and modify their motility patterns to prepare themselves for infection.[12]

Parasite reorientation

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Epimastigotes, which are the culture forms of T. cruzi, swim in the direction of their flagellum, due to tip-to-base symmetrical flagellar beats, that are interrupted by base-to-tip highly asymmetric beats. Switching between both beating modes facilitates parasite reorientation, allowing many movements and trajectories. Epimastigote motility is characterized by alternation of quasi-rectilinear and restricted and complex paths.[12]

Invasion efficiency

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The invasion efficiency is positively correlated with the average parasite mean speed, and negatively correlated with the mean square displacement (MSD). Therefore, the motility modifications undergone by the parasites in the presence of mammalian cells may be functionally related to the cell invasion process.

Moreover, different parasite strains infect different tissues with a variable invasion efficiency, due to the high genetic and phenotypic variability found among T. cruzi strains. T. cruzi trypomastigotes are capable of sensing mammalian cells to a different degree, depending on the cell type, and can modify their motility patterns to increase their invasion efficiency.[12]

Virulence chemistry

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T. cruzi does not produce prostaglandins itself. Instead Pinge-Filho et al. 1999 finds that the parasite induces mice to overproduce 2-series prostaglandins themselves.[20] These PG2s are immunosuppressive and so aid in immune evasion.[20]

Imipramines are trypanocidal.[20] Doyle & Weinbach 1989 find imipramine and various of its derivatives – 3-Chlorimipramine, 2-Nitroimipramine, and 2-Nitrodesmethylimipramine – are trypanocidal in vitro.[20] They find 2-Nitrodesmethylimipramine is the most effective among them.[20]

Epidemiology

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T. cruzi transmission has been documented in the Southwestern U.S., and warming trends may allow vector species to move north. U.S. domestic and wild animals are reservoirs for T. cruzi. Triatomine species in the southern U.S. have taken human blood meals, but because triatomines do not favor typical U.S. housing, risk to the U.S. population is very low.[21]

Chagas' disease's geographical occurrence happens worldwide but high-risk individuals include those who don't have access to proper housing. Its reservoir is in wild animals but its vector is a kissing bug. This is a contagious disease and can be transmitted through a number of ways: congenital transmission, blood transfusion, organ transplantation, consumption of uncooked food that has been contaminated with feces from infected bugs, and accidental laboratory exposure. [citation needed]

Over 130 species can transmit this parasite[22]

Six taxonomic subunits are recognised.[23]

Clinical

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The incubation period is five to fourteen days after a host comes in contact with feces. Chagas disease undergoes two phases, which are the acute and the chronic phase. The acute phase can last from two weeks to two months but can go unnoticed because symptoms are minor and short-lived. Symptoms of the acute phase include swelling, fever, fatigue, and diarrhea. The chronic phase causes digestive problems, constipation, heart failure, and pain in the abdomen. [citation needed]

Diagnostic methods include microscopic examination, serology, or the isolation of the parasite by inoculating blood into a guinea pig, mouse, or rat.[citation needed]

No vaccines are available. The most used method for epidemiological management and disease prevention resides within vector control,[24] mainly by the use of insecticides and taking preventative measures such as applying bug repellent on the skin, wearing protective clothing, and staying in higher quality hotels when traveling. Investing in quality housing would be ideal to decrease risk of contracting this disease.[25]

Genetic exchange

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Genetic exchange has been identified among field populations of T. cruzi.[26] This process appears to involve genetic recombination as well as a meiotic mechanism. Despite the capability for sexual reproduction, natural populations of T. cruzi exhibit clonal population structures. It appears that frequent sexual reproduction events occur primarily between close relatives resulting in an apparent clonal population structure.[27]

See also

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References

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  1. ^ Chagas, C. (1909). "Neue Trypanosomen: Vorläufige mitteilung" [New trypanosome. Preliminary communication]. Archiv für Schiffs-und Tropenhygiene (in German). 13: 120–122.
  2. ^ Chagas, Carlos (1909). "Nouvelle espèce de trypanosomiase humaine" [New species of human trypanosomiasis] (PDF). Bulletin de la Société de Pathologie Exotique (in French). 2 (6): 304–307.
  3. ^ Chagas, C. (1909). "Nova especie morbida do homem, produzida por um Trypanozoma (Trypanozoma cruzi): nota prévia" [New morbid species of man, produced by a Trypanozoma (Trypanozoma cruzi): previous note]. Brazil-Medico (in French). 23 (16): 161.
  4. ^ Kropf, Simone Petraglia; Sá, Magali Romero (July 2009). "The discovery of Trypanosoma cruzi and Chagas disease (1908-1909): tropical medicine in Brazil". História, Ciências, Saúde-Manguinhos. 16: 13–34. doi:10.1590/S0104-59702009000500002. ISSN 0104-5970. PMID 20027916.
  5. ^ Krinsky, William L. (2002). Mullen, Gary; Durden, Lance (eds.). Medical and veterinary entomology. Amsterdam Boston: Academic Press. pp. 67–86/xv–597. doi:10.1016/B978-012510451-7/50007-4. ISBN 978-0-12-510451-7. OCLC 50752006. S2CID 82769743. ISBN 0125104510. ISBN 9780080536071.
  6. ^ Telleria, Jenny; Tibayrenc, Michel, eds. (2017). American trypanosomiasis Chagas disease : one hundred years of research. Amsterdam, Netherlands: Elsevier. doi:10.1016/B978-0-12-801029-7.00007-1. ISBN 978-0-12-801029-7. OCLC 971022099. S2CID 82080107. ISBN 0128010290.
  7. ^ Sant’Anna, Maurício Roberto Viana; Soares, Adriana Coelho; Araujo, Ricardo Nascimento; Gontijo, Nelder Figueiredo; Pereira, Marcos Horácio (2017). "Triatomines (Hemiptera, Reduviidae) blood intake: Physical constraints and biological adaptations". Journal of Insect Physiology. 97. Elsevier: 20–26. doi:10.1016/j.jinsphys.2016.08.004. ISSN 0022-1910. PMID 27521585.
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  12. ^ a b c d Arias-del-Angel, Jorge A.; Santana-Solano, Jesús; Santillán, Moisés; Manning-Cela, Rebeca G. (2020-09-28). "Motility patterns of Trypanosoma cruzi trypomastigotes correlate with the efficiency of parasite invasion in vitro". Scientific Reports. 10 (1): 15894. Bibcode:2020NatSR..1015894A. doi:10.1038/s41598-020-72604-4. ISSN 2045-2322. PMC 7522242. PMID 32985548.
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  15. ^ Marin-Neto, Jose Antonio; Cunha-Neto, Edécio; MacIel, Benedito C.; Simões, Marcus V. (2007). "Pathogenesis of Chronic Chagas Heart Disease". Circulation. 115 (9): 1109–23. doi:10.1161/CIRCULATIONAHA.106.624296. PMID 17339569.
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  17. ^ Baroldi, Giorgio; Oliveira, Samuel J.M; Silver, Malcolm D (1997). "Sudden and unexpected death in clinically 'silent' Chagas' disease. A hypothesis". International Journal of Cardiology. 58 (3): 263–8. doi:10.1016/S0167-5273(96)02878-1. PMID 9076552.
  18. ^ Valente, Ney; Pimenta, João; Paola, Angelo Amato Vincenzo de (2006). "Estudos eletrofisiológicos seriados do sistema éxcito-condutor do coração de pacientes com cardiopatia chagásica crônica" [Serial electrophysiological studies of the heart's excito-conductor system in patients with chronic chagasic cardiopathy]. Arquivos Brasileiros de Cardiologia (in Portuguese). 86 (1): 19–25. doi:10.1590/S0066-782X2006000100004. PMID 16491205.
  19. ^ Benvenuti, Luiz Alberto; Gutierrez, Paulo Sampaio (2007). "Lesões epicárdicas na cardiopatia chagásica são reflexo de processo inflamatório" [Epicardial lesions in Chagas' heart disease reflect an inflammatory process]. Arquivos Brasileiros de Cardiologia (in Portuguese). 88 (4): 496–8. doi:10.1590/S0066-782X2007000400022. PMID 17546284.
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  21. ^ Stevens, Lori; Dorn, Patricia L.; Hobson, Julia; de la Rua, Nicholas M.; Lucero, David E.; Klotz, John H.; Schmidt, Justin O.; Klotz, Stephen A. (2012). "Vector Blood Meals and Chagas Disease Transmission Potential, United States". Emerging Infectious Diseases. 18 (4): 646–649. doi:10.3201/eid1804.111396. PMC 3309679. PMID 22469536.
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  24. ^ Quinde-Calderón, Leonardo; Rios-Quituizaca, Paulina; Solorzano, Luis; Dumonteil, Eric (2016). "Ten years (2004–2014) of Chagas disease surveillance and vector control in Ecuador: Successes and challenges" (PDF). Tropical Medicine & International Health. 21 (1): 84–92. doi:10.1111/tmi.12620. PMID 26458237. S2CID 25754153.
  25. ^ "CDC Works 24/7". Centers for Disease Control and Prevention. Retrieved 2016-04-16.
  26. ^ Messenger LA, Miles MA (2015). "Evidence and importance of genetic exchange among field populations of Trypanosoma cruzi". Acta Trop. 151: 150–5. doi:10.1016/j.actatropica.2015.05.007. PMC 4644990. PMID 26188331.
  27. ^ Berry, Alexander S. F.; Salazar-Sánchez, Renzo; Castillo-Neyra, Ricardo; Borrini-Mayorí, Katty; Chipana-Ramos, Claudia; Vargas-Maquera, Melina; Ancca-Juarez, Jenny; Náquira-Velarde, César; Levy, Michael Z.; Brisson, Dustin; Bartholomeu, Daniella Castanheira (20 May 2019). "Sexual reproduction in a natural Trypanosoma cruzi population". PLOS Neglected Tropical Diseases. 13 (5): e0007392. doi:10.1371/journal.pntd.0007392. PMC 6544315. PMID 31107905.
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