African trypanosome control in the insect vector and mammalian host

2014 ◽  
Vol 30 (11) ◽  
pp. 538-547 ◽  
Author(s):  
Alain Beschin ◽  
Jan Van Den Abbeele ◽  
Patrick De Baetselier ◽  
Etienne Pays
Keyword(s):  
Mammalian Host ◽  
Insect Vector ◽  
African Trypanosome

scholarly journals The Hsp90 chaperone system from the African trypanosome, Trypanosoma brucei

2021 ◽  
Author(s):  
Aileen Boshoff ◽  
Miebaka Jamabo ◽  
Stephen J Bentley ◽  
Paula Macucule-Tinga ◽  
Adrienne Edkins
Keyword(s):  
Heat Shock ◽  
Heat Shock Proteins ◽  
Trypanosoma Brucei ◽  
Molecular Chaperones ◽  
Sub Saharan Africa ◽  
Mammalian Host ◽  
Insect Vector ◽  
Single Chromosome ◽  
African Trypanosome ◽  
Shock Proteins

African Trypanosomiasis is a neglected tropical disease caused by Trypanosoma brucei ( T. brucei ) and is spread by the tsetse fly in sub-Saharan Africa. The disease is fatal if left untreated and the currently approved drugs for treatment are toxic and difficult to administer. The trypanosome must survive in the insect vector and its mammalian host, and to adapt to these different conditions, the parasite relies on molecular chaperones called heat shock proteins. Heat shock proteins mediate the folding of newly synthesized proteins as well as prevent misfolding of proteins under normal conditions and during stressful conditions. Heat shock protein 90 (Hsp90) is one of the major molecular chaperones of the stress response at the cellular level. It functions with other chaperones and co-chaperones and inhibition of its interactions is being explored as a potential therapeutic target for numerous diseases. This study provides an in-silico overview of Hsp90 and its co-chaperones in both T. brucei brucei and T. brucei gambiense in relation to human and other kinetoplastid parasites . The evolutionary, functional, and structural analyses of Hsp90 were also shown. The updated information on Hsp90 and its co-chaperones from recently published proteomics on T. brucei was examined for the different life cycle stages and subcellular localisations. The results show a difference between T. b. brucei and T. b. gambiense with T. b. brucei encoding 12 putative Hsp90 genes, 10 of which are cytosolic and located on a single chromosome while T. gambiense encodes 5 Hsp90 genes, 3 of which are located in the cytosol. Eight putative co-chaperones were identified in this study, 6 TPR-containing and 2 non-TPR-containing co-chaperones. This study provides an updated context for studying the biology of the African trypanosome and evaluating Hsp90 and its interactions as potential drug targets.

scholarly journals Metabolic reprogramming during the Trypanosoma brucei life cycle

F1000Research ◽  
2017 ◽  
Vol 6 ◽  
pp. 683 ◽  
Author(s):  
Terry K. Smith ◽  
Frédéric Bringaud ◽  
Derek P. Nolan ◽  
Luisa M. Figueiredo
Keyword(s):  
Life Cycle ◽  
Trypanosoma Brucei ◽  
Model Organism ◽  
Protozoan Parasite ◽  
Tsetse Fly ◽  
Metabolic Reprogramming ◽  
Mammalian Host ◽  
Insect Vector ◽  
Environmental Signals ◽  
Cellular Metabolic Activity

Cellular metabolic activity is a highly complex, dynamic, regulated process that is influenced by numerous factors, including extracellular environmental signals, nutrient availability and the physiological and developmental status of the cell. The causative agent of sleeping sickness, Trypanosoma brucei, is an exclusively extracellular protozoan parasite that encounters very different extracellular environments during its life cycle within the mammalian host and tsetse fly insect vector. In order to meet these challenges, there are significant alterations in the major energetic and metabolic pathways of these highly adaptable parasites. This review highlights some of these metabolic changes in this early divergent eukaryotic model organism.

Metacyclic variant surface glycoprotein genes of Trypanosoma brucei subsp. rhodesiense are activated in situ, and their expression is transcriptionally regulated

1986 ◽  
Vol 6 (6) ◽  
pp. 1991-1997
Author(s):  
M J Lenardo ◽  
K M Esser ◽  
A M Moon ◽  
L H Van der Ploeg ◽  
J E Donelson
Keyword(s):  
Trypanosoma Brucei ◽  
Gene Deletion ◽  
Surface Glycoprotein ◽  
Mammalian Host ◽  
Small Subset ◽  
Insect Vector ◽  
Gradient Electrophoresis ◽  
Variant Surface Glycoproteins ◽  
Variant Antigen

During the metacyclic stage in the life cycle of Trypanosoma brucei subsp. rhodesiense, the expression of variant surface glycoproteins (VSGs) is restricted to a small subset of antigenic types. Previously we identified cDNAs for the VSGs expressed in metacyclic variant antigen types (MVATs) 4 and 7 and found that these VSG genes do not rearrange when expressed at the metacyclic stage (M. J. Lenardo, A. C. Rice-Ficht, G. Kelly, K. Esser, and J. E. Donelson, Proc. Nathl. Acad Sci. USA 81:6642-6646, 1984). We now provide further evidence that these genes do not rearrange and demonstrate that their 5' upstream regions lack the 72 to 76-base-pair repeats which are considered the substrate for duplication and transposition events. Pulsed field gradient electrophoresis showed that the MVAT VSG genes were located on the largest chromosome-sized DNA molecules, and the lack of the MVAT 4 gene in one of two different serodemes suggested that one mechanism for the evolution of MVAT repertoires is gene deletion. When MVATs were inoculated into the bloodstream of a mammalian host by a bite from the insect vector, they rapidly switched into nonmetacyclic VSG types. We found that this switch was accomplished by a loss of MVAT RNA concomitant with the loss of metacyclic VSGs. Transcription studies with isolated metacyclic nuclei showed that the MVAT genes were expressed in situ from a single locus and were regulated at the level of transcription.

scholarly journals Glucose Signaling Is Important for Nutrient Adaptation during Differentiation of Pleomorphic African Trypanosomes

mSphere ◽  
2018 ◽  
Vol 3 (5) ◽  
Author(s):  
Yijian Qiu ◽  
Jillian E. Milanes ◽  
Jessica A. Jones ◽  
Rooksana E. Noorai ◽  
Vijay Shankar ◽  
...  
Keyword(s):  
Life Cycle ◽  
Glucose Sensing ◽  
Negative Regulator ◽  
Bloodstream Form ◽  
Tsetse Flies ◽  
Insect Vector ◽  
Rapid Reduction ◽  
African Trypanosomes ◽  
Procyclic Form ◽  
African Trypanosome

ABSTRACT The African trypanosome has evolved mechanisms to adapt to changes in nutrient availability that occur during its life cycle. During transition from mammalian blood to insect vector gut, parasites experience a rapid reduction in environmental glucose. Here we describe how pleomorphic parasites respond to glucose depletion with a focus on parasite changes in energy metabolism and growth. Long slender bloodstream form parasites were rapidly killed as glucose concentrations fell, while short stumpy bloodstream form parasites persisted to differentiate into the insect-stage procyclic form parasite. The rate of differentiation was lower than that triggered by other cues but reached physiological rates when combined with cold shock. Both differentiation and growth of resulting procyclic form parasites were inhibited by glucose and nonmetabolizable glucose analogs, and these parasites were found to have upregulated amino acid metabolic pathway component gene expression. In summary, glucose transitions from the primary metabolite of the blood-stage infection to a negative regulator of cell development and growth in the insect vector, suggesting that the hexose is not only a key metabolic agent but also an important signaling molecule. IMPORTANCE As the African trypanosome Trypanosoma brucei completes its life cycle, it encounters many different environments. Adaptation to these environments includes modulation of metabolic pathways to parallel the availability of nutrients. Here, we describe how the blood-dwelling life cycle stages of the African trypanosome, which consume glucose to meet their nutritional needs, respond differently to culture in the near absence of glucose. The proliferative long slender parasites rapidly die, while the nondividing short stumpy parasite remains viable and undergoes differentiation to the next life cycle stage, the procyclic form parasite. Interestingly, a sugar analog that cannot be used as an energy source inhibited the process. Furthermore, the growth of procyclic form parasite that resulted from the event was inhibited by glucose, a behavior that is similar to that of parasites isolated from tsetse flies. Our findings suggest that glucose sensing serves as an important modulator of nutrient adaptation in the parasite.

scholarly journals Evolutionary diversification of the trypanosome haptoglobin-haemoglobin receptor from an ancestral haemoglobin receptor

eLife ◽  
2016 ◽  
Vol 5 ◽  
Author(s):  
Harriet Lane-Serff ◽  
Paula MacGregor ◽  
Lori Peacock ◽  
Olivia JS Macleod ◽  
Christopher Kay ◽  
...  
Keyword(s):  
Developmental Stage ◽  
Trypanosoma Brucei ◽  
Evolutionary History ◽  
Trypanosoma Congolense ◽  
Tsetse Fly ◽  
Mammalian Host ◽  
Trypanosome Species ◽  
African Trypanosome ◽  
Evolutionary Diversification ◽  
Cellular Changes

The haptoglobin-haemoglobin receptor of the African trypanosome species, Trypanosoma brucei, is expressed when the parasite is in the bloodstream of the mammalian host, allowing it to acquire haem through the uptake of haptoglobin-haemoglobin complexes. Here we show that in Trypanosoma congolense this receptor is instead expressed in the epimastigote developmental stage that occurs in the tsetse fly, where it acts as a haemoglobin receptor. We also present the structure of the T. congolense receptor in complex with haemoglobin. This allows us to propose an evolutionary history for this receptor, charting the structural and cellular changes that took place as it adapted from a role in the insect to a new role in the mammalian host.

scholarly journals Targeted Disruption of the Plasmodium berghei Ctrp Gene Reveals Its Essential Role in Malaria Infection of the Vector Mosquito

1999 ◽  
Vol 190 (11) ◽  
pp. 1711-1716 ◽  
Author(s):  
Masao Yuda ◽  
Hiroshi Sakaida ◽  
Yasuo Chinzei
Keyword(s):  
Plasmodium Berghei ◽  
Malaria Infection ◽  
Molecular Mechanisms ◽  
Mammalian Host ◽  
Insect Vector ◽  
Wild Type ◽  
Mosquito Midgut ◽  
Parasite Plasmodium ◽  
Vector Mosquito ◽  
Stage 1

CTRP (circumsporozoite protein and thrombospondin-related adhesive protein [TRAP]-related protein) of the rodent malaria parasite Plasmodium berghei (PbCTRP) makes up a protein family together with other apicomplexan proteins that are specifically expressed in the host-invasive stage 1. PbCTRP is produced in the mosquito-invasive, or ookinete, stage and is a protein candidate for a role in ookinete adhesion and invasion of the mosquito midgut epithelium. To demonstrate involvement of PbCTRP in the infection of the vector, we performed targeting disruption experiments with this gene. PbCTRP disruptants showed normal exflagellation rates and development into ookinetes. However, no oocyst formation was observed in the midgut after ingestion of these parasites, suggesting complete loss of their invasion ability. On the other hand, when ingested together with wild-type parasites, disruptants were able to infect mosquitoes, indicating that the PbCTRP gene of the wild-type parasite rescued infectivity of disruptants when they heterologously mated in the mosquito midgut lumen. Our results show that PbCTRP plays a crucial role in malaria infection of the mosquito midgut and suggest that similar molecular mechanisms are used by malaria parasites to invade cells in the insect vector and the mammalian host.

scholarly journals Poly-N-Acetylglucosamine Expression by Wild-Type Yersinia pestis Is Maximal at Mammalian, Not Flea, Temperatures

mBio ◽  
2012 ◽  
Vol 3 (4) ◽  
Author(s):  
Pauline Yoong ◽  
Colette Cywes-Bentley ◽  
Gerald B. Pier
Keyword(s):  
Yersinia Pestis ◽  
Congo Red ◽  
Biofilm Formation ◽  
Mammalian Host ◽  
Virulence Plasmid ◽  
Insect Vector ◽  
Wild Type ◽  
Content Type ◽  
Higher Temperature ◽  
Mammalian Infection

ABSTRACTNumerous bacteria, includingYersinia pestis, express the poly-N-acetylglucosamine (PNAG) surface carbohydrate, a major component of biofilms often associated with a specific appearance of colonies on Congo red agar. Biofilm formation and PNAG synthesis byY. pestishave been reported to be maximal at 21 to 28°C or “flea temperatures,” facilitating the regurgitation ofY. pestisinto a mammalian host during feeding, but production is diminished at 37°C and thus presumed to be decreased during mammalian infection. Most studies of PNAG expression and biofilm formation byY. pestishave used a low-virulence derivative of strain KIM, designated KIM6+, that lacks the pCD1 virulence plasmid, and an isogenic mutant without the pigmentation locus, which contains the hemin storage genes that encode PNAG biosynthetic proteins. Using confocal microscopy, fluorescence-activated cell sorter analysis and growth on Congo red agar, we confirmed prior findings regarding PNAG production with the KIM6+ strain. However, we found that fully virulent wild-type (WT) strains KIM and CO92 had maximal PNAG expression at 37°C, with lower PNAG production at 28°C both in broth medium and on Congo red agar plates. Notably, the typical dark colony morphology appearing on Congo red agar was maintained at 28°C, indicating that this phenotype is not associated with PNAG expression in WTY. pestis. Extracts of WT sylvaticY. pestisstrains from the Russian Federation confirmed the maximal expression of PNAG at 37°C. PNAG production by WTY. pestisis maximal at mammalian and not insect vector temperatures, suggesting that this factor may have a role during mammalian infection.IMPORTANCEYersinia pestistransitions from low-temperature residence and replication in insect vectors to higher-temperature replication in mammalian hosts. Prior findings based primarily on an avirulent derivative of WT (wild-type) KIM, named KIM6+, showed that biofilm formation associated with synthesis of poly-N-acetylglucosamine (PNAG) is maximal at 21 to 28°C and decreased at 37°C. Biofilm formation was purported to facilitate the transmission ofY. pestisfrom fleas to mammals while having little importance in mammalian infection. Here we found that for WT strains KIM and CO92, maximal PNAG production occurs at 37°C, indicating that temperature regulation of PNAG production in WTY. pestisis not mimicked by strain KIM6+. Additionally, we found that Congo red binding does not always correlate with PNAG production, despite its widespread use as an indicator of biofilm production. Taken together, the findings show that a role for PNAG in WTY. pestisinfection should not be disregarded and warrants further study.

Detection of thiol-based redox switch processes in parasites – facts and future

2015 ◽  
Vol 396 (5) ◽  
pp. 445-463 ◽  
Author(s):  
Mahsa Rahbari ◽  
Kathrin Diederich ◽  
Katja Becker ◽  
R. Luise Krauth-Siegel ◽  
Esther Jortzik
Keyword(s):  
Fluorescent Dyes ◽  
Redox Homeostasis ◽  
Life Cycles ◽  
Detection Methods ◽  
Mammalian Host ◽  
Host Immune System ◽  
Insect Vector ◽  
Comprehensive Overview ◽  
Specificity And Sensitivity ◽  
Antiparasitic Drugs

Abstract Malaria and African trypanosomiasis are tropical diseases caused by the protozoa Plasmodium and Trypanosoma, respectively. The parasites undergo complex life cycles in the mammalian host and insect vector, during which they are exposed to oxidative and nitrosative challenges induced by the host immune system and endogenous processes. Attacking the parasite’s redox metabolism is a target mechanism of several known antiparasitic drugs and a promising approach to novel drug development. Apart from this aspect, oxidation of cysteine residues plays a key role in protein-protein interaction, metabolic responses to redox events, and signaling. Understanding the role and dynamics of reactive oxygen species and thiol switches in regulating cellular redox homeostasis is crucial for both basic and applied biomedical approaches. Numerous techniques have therefore been established to detect redox changes in parasites including biochemical methods, fluorescent dyes, and genetically encoded probes. In this review, we aim to give an insight into the characteristics of redox networks in the pathogens Plasmodium and Trypanosoma, including a comprehensive overview of the consequences of specific deletions of redox-associated genes. Furthermore, we summarize mechanisms and detection methods of thiol switches in both parasites and discuss their specificity and sensitivity.

scholarly journals Investigating the Chaperone Properties of a Novel Heat Shock Protein, Hsp70.c, fromTrypanosoma brucei

2014 ◽  
Vol 2014 ◽  
pp. 1-12 ◽  
Author(s):  
Adélle Burger ◽  
Michael H. Ludewig ◽  
Aileen Boshoff
Keyword(s):  
Heat Shock ◽  
Heat Shock Protein ◽  
Trypanosoma Brucei ◽  
Mammalian Host ◽  
Insect Vector ◽  
Wide Range ◽  
Response To Stress ◽  
Parasite Biology ◽  
Substrate Binding Domain

The neglected tropical disease, African Trypanosomiasis, is fatal and has a crippling impact on economic development. Heat shock protein 70 (Hsp70) is an important molecular chaperone that is expressed in response to stress and Hsp40 acts as its co-chaperone. These proteins play a wide range of roles in the cell and they are required to assist the parasite as it moves from a cold blooded insect vector to a warm blooded mammalian host. A novel cytosolic Hsp70, fromTrypanosoma brucei, TbHsp70.c, contains an acidic substrate binding domain and lacks the C-terminal EEVD motif. The ability of a cytosolic Hsp40 fromTrypanosoma bruceiJ protein 2, Tbj2, to function as a co-chaperone of TbHsp70.c was investigated. The main objective was to functionally characterize TbHsp70.c to further expand our knowledge of parasite biology. TbHsp70.c and Tbj2 were heterologously expressed and purified and both proteins displayed the ability to suppress aggregation of thermolabile MDH and chemically denatured rhodanese. ATPase assays revealed a 2.8-fold stimulation of the ATPase activity of TbHsp70.c by Tbj2. TbHsp70.c and Tbj2 both demonstrated chaperone activity and Tbj2 functions as a co-chaperone of TbHsp70.c.In vivoheat stress experiments indicated upregulation of the expression levels of TbHsp70.c.

scholarly journals Surface Sialic Acids Taken from the Host Allow Trypanosome Survival in Tsetse Fly Vectors

2004 ◽  
Vol 199 (10) ◽  
pp. 1445-1450 ◽  
Author(s):  
Kisaburo Nagamune ◽  
Alvaro Acosta-Serrano ◽  
Haruki Uemura ◽  
Reto Brun ◽  
Christina Kunz-Renggli ◽  
...  
Keyword(s):  
Salivary Gland ◽  
Trypanosoma Brucei ◽  
Sialic Acids ◽  
Sleeping Sickness ◽  
Tsetse Fly ◽  
Mammalian Host ◽  
Tsetse Flies ◽  
African Trypanosome ◽  
Blood Sucking

The African trypanosome Trypanosoma brucei, which causes sleeping sickness in humans and Nagana disease in livestock, is spread via blood-sucking Tsetse flies. In the fly's intestine, the trypanosomes survive digestive and trypanocidal environments, proliferate, and translocate into the salivary gland, where they become infectious to the next mammalian host. Here, we show that for successful survival in Tsetse flies, the trypanosomes use trans-sialidase to transfer sialic acids that they cannot synthesize from host's glycoconjugates to the glycosylphosphatidylinositols (GPIs), which are abundantly expressed on their surface. Trypanosomes lacking sialic acids due to a defective generation of GPI-anchored trans-sialidase could not survive in the intestine, but regained the ability to survive when sialylated by means of soluble trans-sialidase. Thus, surface sialic acids appear to protect the parasites from the digestive and trypanocidal environments in the midgut of Tsetse flies.

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