African Sleeping Sickness: Tyrpanosome Invasion Mechanism

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Introduction

The insect vector of the trypanosome microbe, the tsetse fly. These flies are found in tropical parts of Southern Africa and are the only known vector for African Sleeping Sickness [1].


By Katie Lensmeyer



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African Sleeping Sickness is a microbial vector driven disease that affects many parts of Africa. The disease takes action by first invading the peripheral nervous system of its host and soon after passes the blood brain barrier to damage neurons within the brain. The result of this infection is fatal to the mammalian host. From initial infection to death of the host system, this microbe needs only a few short months to become fatal. How is it that this disease can invade such secure parts of the human system so quickly? The human immune system seems to be far to advanced to let this microbe produce the affects it does. Recent research looks deeply into both the spread of the infection through the mammalian host as well as the growth of the microbe within its vector, the tsetse fly.

The relationship between the tsetse fly and T. Breci is that of an obligate parasite, meaning the cell needs a host cell in order to function. Once transmitted from the tsetse fly to a mammal, the microbe becomes pathogenic. Unsurprisingly, across the 36 African countries that it is found in, the tsetse fly is known to carry a variety of trypanosomiasis infections. The tsetse fly is immune to all of the trypanosome diseases that they transmit. This protection comes down to their lack of hemolymph within their blood. Their nutrient availability can no provide the microbe with the nourishment needed in order for the trypanosome cells to replicate into their pathogenic form. The cell does however have a mild affect on its fly host in the way that any normal parasite-host relationship would.

Phylogenetic reconstruction of this disease has shown that this disease has existed for approximately 300 million years. The microbial coexistence with its insect parasites has existed for equally as long. This ancient coexistence between African mammals and their blood-sucking insect counterparts is assumed to be why most native Animalia are not affected by the disease. This immunity, however, does not stretch to the domesticated animals of the area. Trypanosome breci, the form of trypanosomes that causes sleeping sickness, is expected to be a recent development within history of trypanosomes. Most researchers suspect this because Trypanosome breci is the only trypanosome microbe that humans are not resistant to. [1]

Sleeping Sickness is a unique microbe that, despite its phylogenetic relatives, is extremely pathogenic to humans and other mammals. What is the disease mechanism to this harmful cell? Research explored here aims to explain the inoculation of the disease within both the host and the parasite, as well as explains how the unique symptoms of the disease are produced within the infected human host.


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What is African Sleeping Sickness?

African Sleeping Sickness affects 30,000 people every year. The disease has been found in 37 African countries, all in the Sub-Saharan areas. [2].


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African Trypanosomiasis, or better known as African Sleeping Sickness, is a parasite driven infection of the human nervous system. The disease is caused by the microbial parasites of the species Trypanosoma brucei and than transmitted through the tsetse fly, found only in rural parts of Africa. Throughout history, this disease has been classified as a public health problem seen primarily in sub-saharan areas of Africa. About 10,000 cases of the disease are reported every year to the World Health organization, but unfortunately it is expected that most cases go unreported and/or undiagnosed.
[4]
Because this disease is vector borne, the microbe, trypanosome brucei, enters the human system by ways of the skin. An infected tsetse fly must bite the host, and through this wound the protozoan enters the system. After initial infection, the disease has two stages. The first of these stages is the time in which the parasite is found within the peripheral nervous system, but has not yet made its way into the central nervous system. The second stage begins when the infection has passed the blood brain barrier and resides within the central nervous system. The disease than acts quickly, leaving its host with symptoms of fever, tremors, swollen lymph nodes, sleep disturbances, and speech problems within the first two weeks of infection. Following weeks lead to neurological deterioration ending in coma and soon after death. An untreated case can expect the the disease to become fatal within a few months. [5]

Cell Structure and Function

The trypanosome cell amongst red blood cells.


Trypanosoma cells are small (approxiamtely 50um) and heterotrophic, meaning they do not generate their own food source. The shape of the cell itself is long and oval with curved edges with a strong flagellum projecting off of the back end of the cell. The cell holds its struture through the presence of a highly polarized microtubule cytoskeleton. This cytoskeleton provides defiinite locations for the cell’s organelles (i.e. the flagellar pocket, flagellum, kinetoplast, mitochondrion and nucleus) within the center and posterior ends of the cell (end opposite of the flagella). [6] This cell expresses traits within its structure that are rather unique. Analogous to what is seen in its phylum Euglenozoa, the cell has a stiffening paraxial rod within its flagellum. Similarities with members of the cells order, Kinetoplastida, exist as well. The Trypansoma cell expresses a large cluster of DNA at the opposite end of the cell from the flagellum. This clump of DNA, otherwise known as the kinetoplast, extends from the cell’s unusually long mitochondrion and functions to determine its form within its human host. [7]

Upon initial entry into the host environment, the microbe finds itself floating within the bloodstream of the mammal in which it infected. This part of the human system is flowing with host defense mechanisms, both innate and adaptive immune responses, ready to attack any intruder. Trypanosoma has evolved to travel through this environment without detection through the presence of variant surface glycoproteins (VSG) that coat its cell wall. These VSG express one of ~1500 surface glycoprotein genes. The gene used to express these proteins changes with every 100th replication cycle to ensure the infections longevity. Upon detection, the host immune system will begin launching a complimentary protection response against trypanosoma. The change in transcription of the glycoprotein genes ensures that this complementary immune response is ineffective against the pathogen because the new VSG have developed and are undetectable. This characteristic is why patients with trypanosomiasis often experience symptoms of the disease followed by a period of latency. The disease has not dissipated but rather evaded the developed defenses of the host cell. These VSG properties are only found at certain times within the cells lifecycle: when the cell is developing within the saliva of the tsetse fly and when traveling through the host's bloodstream.

Inoculation Within the Insect Vector

The life cycle and cell shape of trypanosoma breci within the tsetse fly vector


The only known vector for the disease is the tsetse fly, which can be found all over Sub-Saharan Africa. Strangely, the tsetse fly acquire the trypanosoma microbe from biting infected animals or humans who conceal pathogenic parasites. [8] Once an individual fly gains the pathogenic cell, it modifies itself into a form that can be delivered and infect human hosts. In order to transform into the correct version of itself, the cell undergoes a series of developemental cycles including cell division to prepare themselves for infection. This augmentation within the insect can be sectioned into three different stages: the procyclic form, the epimastigote form and the metacyclic form. The procyclic and epimastigote forms exist for multiplication purposes, whereas the metacyclic form functions as an adaptation period inorder to effectively integrate itself within a human host. [9]

Upon entrance into the insect from ingesting an infected human’s blood, the so called “stumpy” form of T. breci enters and must adjust itself to survive within the environemnt of the fly. This intial transformation is composed of a varitey of reactions that are not yet fully understood. Many suspect that proteases within the insect’s midgut ignite a trigger response to the new environment. Beyond this idea, some believe that the microbe posses a cold-shock response that appears as the microbe travels from the warm-blooded human to the exothermic fly. Despite the controversy of this initial transformation, the “stumpy” form of the trypanosome remodels into the first form, the procyclic form, which than quickly attaches to the cells of the ectoperitrophic space and begin their growth into a more motile form. This form is also called the trypomastigote. The trypomastigote moves rather rapidly up the midgut of the insect and into the salivary glands. By connection to the kinetoplast, the cell enters the second, epimastigote form. This long form resides and begins replication within the salivary gland cell membranes. The cell must soon divide to form the short epimastigote form. This developmental form is currently considered to be responsible for the growth of the metacyclic trypanosomes that arre found prior to the cellular infection of a mammalian host. This cell division process is currently a popular research topic. The specifics of this differntiation is not fully understood. However, research has proven that relocation of the kinetoplast is vital to the growth of long epimastigote cells.

Section 3

Include some current research, with at least one figure showing data.

Section 4

Conclusion

References

  1. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2270819/=PDF Steverding, Dietmar. “The History of African Trypanosomiasis.” Parasites & Vectors, BioMed Central, 2008
  2. Hodgkin, J. and Partridge, F.A. "Caenorhabditis elegans meets microsporidia: the nematode killers from Paris." 2008. PLoS Biology 6:2634-2637.
  3. Bartlett et al.: Oncolytic viruses as therapeutic cancer vaccines. Molecular Cancer 2013 12:103.
  4. https://www.cdc.gov/parasites/sleepingsickness/=PDF “Disease.” Centers for Disease Control and Prevention, Centers for Disease Control and Prevention, 29 Aug. 2012, www.cdc.gov/parasites/sleepingsickness/disease.html.
  5. https://www.cdc.gov/parasites/sleepingsickness/disease.html=PDF “Disease.” Centers for Disease Control and Prevention, Centers for Disease Control and Prevention, 29 Aug. 2012
  6. [http://jcs.biologists.org/content/118/2/283=PDF Matthews, Keith R. “The Developmental Cell Biology of Trypanosoma Brucei.” Journal of Cell Science, The Company of Biologists Ltd, 15 Jan. 2005, jcs.biologists.org/content/118/2/283.
  7. https://microbewiki.kenyon.edu/index.php/Trypanosoma=PDF “Disease.” “Trypanosoma.” Trypanosoma - Microbewiki, 7 Aug. 2010
  8. http://www.who.int/mediacentre/factsheets/fs259/en/=PDF WHO. “Trypanosomiasis, Human African (Sleeping Sickness).” World Health Organization, World Health Organization, 21 Mar. 2017
  9. https://microbewiki.kenyon.edu/index.php/Trypanosome_Life_Cycle=PDF “Trypanosome Life Cycle.” Trypanosome Life Cycle - Microbewiki, 10 Aug. 2010



Authored for BIOL 238 Microbiology, taught by Joan Slonczewski, 2018, Kenyon College.