Difference between revisions of "Trypanosoma cruzi"

From MicrobeWiki, the student-edited microbiology resource
(One intermediate revision by one other user not shown)
Line 1: Line 1:
{{Biorealm Genus}}
{{Biorealm Genus}}
Line 5: Line 6:
===Higher order taxa===
===Higher order taxa===
Protozoa; Euglenozoa; Trypanosomatidae; Kinetoplast; Trypanosomataceae  [http://www.ncbi.nlm.nih.gov/Taxonomy/ NCBI]
Protozoa; Euglenozoa; Trypanosomatidae; Trypanosomataceae  [http://www.ncbi.nlm.nih.gov/Taxonomy/ NCBI]
=== Genus and Species===
=== Genus and Species===

Latest revision as of 03:38, 20 August 2010

This student page has not been curated.

A Microbial Biorealm page on the genus Trypanosoma cruzi

Classification [1]

Higher order taxa

Protozoa; Euglenozoa; Trypanosomatidae; Trypanosomataceae NCBI

Genus and Species

NCBI: Taxonomy

Trypanosoma Cruzi

Description and significance

Trypanosoma Cruzi (T. Cruzi) is a kinetoplast eukaryotic cell that is associated with causing the often fatal Chagas Disease, which spreads through insects [3]. The two main lineages that are specifically linked to the disease are T. Cruzi I and T. Cruzi II [2]. Chagas Disease, which is mainly found in South America, is characterized by organ failure, usually in the digestive tract and heart [6]. The invasion of T. Cruzi involves the parasite converting into trypomastigotes and amastigotes. These parasitic forms are characteristic of the Trypanosoma life cycle [5]. Figure 1 shows the complete life cycle.

T. Cruzi goes through three main forms. There is the epimastigote, which is the form found in the insect. There is the amastigote form which is found in the cytosol of cells. And there is the trypomastigote that is found in the bloodstream. There are currently very few drugs available to combat Chagas Disease. The two most common ones are nifurtimox and benznidazole. Benznidazole has limited effectiveness and only works in eliminating T. Cruzi when the disease is mildy chronic. There is no treatment for the more advanced forms of the illness [11]. Thus, it is important for this microbe to be fully understood so as to create treatments for this debilitating disease.

AmerTryp LifeCycle.jpeg [4]

Genome structure

The genome of T. Cruzi has been fully sequenced. Over half of it consists of repeats, which include the many surface proteins that are needed for invasion. It has been predicted that 22,570 proteins are encoded. The genome shows that there are two different lineages, T. Cruzi I andT. Cruzi II. The two have an average sequence divergence of 5.4%. T. Cruzi I infects marsupials and T. Cruzi II infects placental mammals. The sequenced strain is T. Cruzi CL Brener, which is part of T. Cruzi II. The genome had 8740 contigs, with a total size of 67 Mb. The diploid size is approximated to be between 106.4 Mb and 110.7 Mb long. The GC content of the genome is about 51% [12].

Telomerase enzymes are an important part of the life cycle of T. Cruzi. The telomeric repeat of 5’TTAGGG3’ is the same as in mammals which suggests an evolutionary link. Telomeres are involved in primer elongation and primer and product cleaving. Studies have suggested that telomerase plays a role in all aspects of development, even when the cell is not actively proliferating [8].

Cell structure and metabolism

Calcium is very important to the survival of T. Cruzi. Since a large amount of it is needed for invasion, it is important for the cell to have large stores of calcium ready for use. This is because amastigotes live in the cytosol, not in the extracellular space as most eukaryotic cells. The cytosol has a very low concentration of calcium so having intracellular stores is vital. The calcium is stored in a special organelle known as the acidocalcisome, which is not found in most other eukaryotic cells. The acidocalcisome employs ATPase to take up calcium and export protons [5]. T. Cruzi makes heavy use of the host cell to perform its essential cellular processes. Examples include calcium, growth factors, cAMP, and various kinases. One such protein kinase that is important for invasion and found in the host cell is casein kinase II (CKII). CKII phosphorylates a cell surface protein, Tc-1, that is only found in invasive trypomastigotes. Studies have shown that CKII produces many enzymes that are essential for cell survival, including regulation and biosynthesis. Since Tc-1 is only found on the pathogenic trypomastigotes, it can be inferred that Tc-1 is necessary for the pathogenic traits of the microbe. T. Cruzi does have some of its own mechanisms to help in invasion. For instance, to aid in the attachment to the host cell, T. Cruzi, using phospholipase C, also releases glycosylphosphatidylinositol molecules that attach to the membrane [7].


T. Cruzi is most often spread through the reduviid insect, which bites the host and then leaves excrement with the pathogen near the open wound. It is most prevalent in the rural and poorer areas of Latin America [10].


T. Cruzi causes Chagas Disease by invading mammalian cells. They show no specificity and can invade many different cell types. T. Cruzi spreads among mammals through hematophagous triatomines insect. It is known to cause chronic symptoms of various digestive problems and by causing the more serious problem of weakening the heart muscle. Once in the host, the resulting trypomastigotes then separate into different amastigotes, with each one corresponding to a different mammal cell for which to invade so as to cause the maximum infection. The parasite is then free to multiply and divide through binary fission and will spread to other cells after causing cell lysis and turning back into trypomastigotes as it looks for other cells to invade [3]. A more complete version of the life cycle is shown in Figure 1.

There are many pathways that are involved in the invasion. One such pathway utilizes Ca2+ signaling. Studies have shown that an increase in the calcium concentration in the cytosol of the trypomastigotes is associated with invasion and a decrease in the calcium concentration hinders invasion [5].

After invasion, the trypomastigotes turn into amastigotes. This differentiation involves a significant transformation of the plasma membrane. The plasma membrane contains lipids known as IPC and PI. These are made and rearranged to fit the new form of the pathogen [9].

Current Research

There is still a lot of research being done on T. Cruzi, mainly in the area of finding effective ways to combat Chagas Disease, which still has no cure. For instance, there have been many studies that have examined the effectiveness of DNA vaccines against T. Cruzi. These DNA plasmids are helpful because they induce a total immune response. They are also very safe for they don’t contain any pathogenic form of an organism so no danger is posed. The first testing with the DNA vaccines was done using the trans-sialidase proteins, which are surface proteins on T. Cruzi. Studies showed that activity of these surface proteins was inhibited when the plasmid was injected and survival did increase for vaccinated mice. However, more research must be done to see if other surface proteins can be inhibited for trans-sialidase proteins are only one type among many [13].

Another way to eradicate Chagas Disease is to look to its source, the insects that carry it. Studies have been undertaken to try to stop infestations of the reduviid bug. This is the main way the World Health Organization has used to attempt to stop the spread of the disease. After an insecticide is applied to a known infestation, the main problem is keeping that area reduviid-free. To stop the re-infestation, population behaviour and environmental factors must be understood. For instance, repopulation of the areas varied among the different seasons. Studies have also shown that infestations did not differ between areas treated with insecticide and area that were not [14]. However, the number of overall populations has reduced [16]. More studies must be undertaken to better understand the factors that govern population growth and establishment, including finding the most favorable time of the year to spray insecticide [14].

Other studies have chosen to focus on the cellurlar organization and transduction pathways that T. Cruzi has. It has been found that trypanosomes have specialized and unique structures that help with organization. For instance, they have the glycosome which has all the enzymes needed for the pentose phosphate pathway. One such study focused on arginine kinase which has a role in storing energy. It was seen that the expression of this kinase allowed for a higher rate of survival for T. Cruzi. In this case, arginine kinase was crystallized and studied. Understanding the pathways that take place in the microbe can lead to more options for drugs to target [15].


[1] GBIF: Trypanosoma Cruzi, Accessed August 23, 2007 <http://www.asia.gbif.net/portal/ecat_browser.jsp?taxonKey=2148331>

[2] Lages-Silva, Eliane, Ramirez, Luis Eduardo, et al. “Variability of Kinetoplast DNA Gene Signatures of Trypanosoma Cruzi II Strains from Patients with Different Clinical Forms of Chagas’ Disease in Brazil.” Journal of Clinical Microbiology, June 2006; 44: 2167-2171.

[3] Aparicio, Isabela M., Scharfstein, Julio, Lima, Ana Paula C.A. “A New Cruzipain-Mediated Pathway of Human Cell Invasion by Trypanosoma cruzi Requires Trypomastigote Membranes.” Infection and Immunity, October 2004; 72: 5892-5902.

[4] http://www.dpd.cdc.gov/dpdx/HTML/TrypanosomiasisAmerican.htm (for picture)

[5] Lu, Hong-Gang, Zhong, Li, et al. “Ca2+ Content and Expression of an Acidocalcisomal Calcium Pump Are Elevated in Intracellular Forms of Trypanosoma cruzi.” Molecular and Cellular Biology, April 1998; 18: 2309-2323.

[6] Naula, Christina, Parsons, Marilyn, and Mottram, Jeremy C. “Protein kinases as drug targets in trypanosomes and Leishmania.” Biochim Biophys Acta, Dec 2005; 1754: 151-159.

[7] Augustine, Swinburn A.J., Kleshchenko, Yuliya A., et al. “Molecular Cloning of a Trypanosoma cruzi Cell Surface Casein Kinase II Substrate, Tc-1, Involved in Cellular Infection.” Infection and Immunity, July 2006; 74: 3922-3929.

[8] Munoz, Denise P. and Collins, Kathleen. “Biochemical properties of Trypanosoma cruzi telomerase.” Nucleic Acids Research, Sept 2005; 32: 5214-5222.

[9] Salto, Maria Laura, Bertello, Laura E., et al. “Formation and Remodeling of Inositolphosphoceramide during Differentiation of Trypanosoma cruzi from Trypomastigote to Amastigote.” Eukaryotic Cell, August 2003; 2: 756-768.

[10] Tanowitz, H B, Kirchhoff, L V, et al. “Chagas Disease.” Clinical Microbiology Reviews, Oct 1992; 5: 400-419.

[11] Garcia, Simone, Ramos, Caroline O., et al. “Treatment with Benznidazole during the Chronic Phase of Experimental Chagas' Disease Decreases Cardiac Alterations.” Antomicrobial Agents and Chemotherapy, April 2005; 49: 1521-1528.

[12] El-Sayed, Najib M., Myler, Peter J., et al. “The Genome Sequence of Trypanosoma cruzi, Etiologic Agent of Chagas Disease.” Science, July 2005; 309: 409-415.

[13] Dumonteil, Eric. “DNA Vaccines against Protozoan Parasites: Advances and Challenges.” Journal of Biomedicine and Biotechnology, June 2007; published online.

[14] Dohna, Heinrich Zu, Cecere, Maria C., et al. “Re-establishment of local populations of vectors of Chagas disease after insecticide spraying.” Journal of Applied Ecology, Feb 2007; 44: 220-227.

[15] Fernandez, Pablo, haouz, Ahmed, et al. "The crystal structure of Trypanosoma cruzi arginine kinase." Proteins, July 2007; 69: 209-212.

[16] Pizarro, Juan Carlos, Lucero, David E., Stevens, Lori. “PCR reveals significantly higher rates of Trypanosoma cruzi infection than microscopy in the Chagas vector, Triatoma infestans: High rates found in Chuquisaca, Bolivia.” BMC Infectious Disease, June 2007; published online.

Edited by Shruti Jayakumar, student of Rachel Larsen