scholarly journals Unexpected plasticity in the life cycle of Trypanosoma brucei

2019 ◽  
Author(s):  
Sarah Schuster ◽  
Ines Subota ◽  
Jaime Lisack ◽  
Henriette Zimmermann ◽  
Christian Reuter ◽  
...  
Keyword(s):  
Life Cycle ◽  
Parasite Load ◽  
Tsetse Fly ◽  
Productive Infection ◽  
Complex Life Cycle ◽  
Tsetse Flies ◽  
Chronic Infections ◽  
African Trypanosomes ◽  
Life Cycle Stages ◽  
Shed Light

AbstractAfrican trypanosomes cause sleeping sickness in humans and nagana in cattle. These unicellular parasites are transmitted by the bloodsucking tsetse fly. In the mammalian host’s circulation, tissues, and interstitium, at least two main life cycle stages exist: slender and stumpy bloodstream stages. Proliferating slender stage cells differentiate into cell cycle-arrested stumpy stage cells at high population densities. This developmental stage transition occurs in response to the quorum sensing factor SIF (stumpy induction factor), and is thought to fulfil two main functions. First, it auto-regulates the parasite load in the host. Second, the stumpy stage is regarded as pre-adapted for tsetse fly infection and the only stage capable of successful vector transmission. Here, we show that proliferating slender stage trypanosomes are able to complete the complex life cycle in the fly as successfully as the stumpy stage, and that a single parasite is sufficient for productive infection. Our findings not only propose a revision to the traditional rigid view of the trypanosome life cycle, but also suggest a solution to a long-acknowledged paradox in the transmission event: parasitaemia in chronic infections is characteristically low, and so the probability of a tsetse ingesting a stumpy cell during a bloodmeal is also low. The finding that proliferating slender parasites are infective to tsetse flies helps shed light on this enigma.

scholarly journals Unexpected plasticity in the life cycle of Trypanosoma brucei

eLife ◽  
2021 ◽  
Vol 10 ◽  
Author(s):  
Sarah Schuster ◽  
Jaime Lisack ◽  
Ines Subota ◽  
Henriette Zimmermann ◽  
Christian Reuter ◽  
...  
Keyword(s):  
Life Cycle ◽  
Trypanosoma Brucei ◽  
Parasite Load ◽  
Tsetse Fly ◽  
Productive Infection ◽  
Complex Life Cycle ◽  
Chronic Infections ◽  
Population Densities ◽  
African Trypanosomes ◽  
Stage Transition

African trypanosomes cause sleeping sickness in humans and nagana in cattle. These unicellular parasites are transmitted by the bloodsucking tsetse fly. In the mammalian host's circulation, proliferating slender stage cells differentiate into cell cycle-arrested stumpy stage cells when they reach high population densities. This stage transition is thought to fulfil two main functions: first, it auto-regulates the parasite load in the host; second, the stumpy stage is regarded as the only stage capable of successful vector transmission. Here, we show that proliferating slender stage trypanosomes express the mRNA and protein of a known stumpy stage marker, complete the complex life cycle in the fly as successfully as the stumpy stage, and require only a single parasite for productive infection. These findings suggest a reassessment of the traditional view of the trypanosome life cycle. They may also provide a solution to a long-lasting paradox, namely the successful transmission of parasites in chronic infections, despite low parasitemia.

scholarly journals Intraflagellar transport during the assembly of flagella of different length in Trypanosoma brucei isolated from tsetse flies

2020 ◽  
Author(s):  
Eloïse Bertiaux ◽  
Adeline Mallet ◽  
Brice Rotureau ◽  
Philippe Bastin
Keyword(s):  
Life Cycle ◽  
Trypanosoma Brucei ◽  
Live Cell Imaging ◽  
Intraflagellar Transport ◽  
Tsetse Fly ◽  
Tsetse Flies ◽  
Life Cycle Stages ◽  
Summary Statement ◽  
Cilia And Flagella ◽  
Multicellular Organisms

AbstractMulticellular organisms assemble cilia and flagella of precise lengths differing from one cell to another, yet little is known about the mechanisms governing these differences. Similarly, protists assemble flagella of different lengths according to the stage of their life cycle. This is the case of Trypanosoma brucei that assembles flagella of 3 to 30 µm during its development in the tsetse fly. It provides an opportunity to examine how cells naturally modulate organelle length. Flagella are constructed by addition of new blocks at their distal end via intraflagellar transport (IFT). Immunofluorescence assays, 3-D electron microscopy and live cell imaging revealed that IFT was present in all life cycle stages. IFT proteins are concentrated at the base, IFT trains are located along doublets 3-4 & 7-8 and travel bidirectionally in the flagellum. Quantitative analysis demonstrated that the total amount of IFT proteins correlates with the length of the flagellum. Surprisingly, the shortest flagellum exhibited a supplementary large amount of dynamic IFT material at its distal end. The contribution of IFT and other factors to the regulation of flagellum length is discussed.Summary statementThis work investigated the assembly of flagella of different length during the development of Trypanosoma brucei in the tsetse fly, revealing a direct correlation between the amount of intraflagellar transport proteins and flagellum length.

scholarly journals Intraflagellar transport during assembly of flagella of different length in Trypanosoma brucei isolated from tsetse flies

2020 ◽  
Vol 133 (18) ◽  
pp. jcs248989
Author(s):  
Eloïse Bertiaux ◽  
Adeline Mallet ◽  
Brice Rotureau ◽  
Philippe Bastin
Keyword(s):  
Life Cycle ◽  
Trypanosoma Brucei ◽  
Live Cell Imaging ◽  
Intraflagellar Transport ◽  
Tsetse Fly ◽  
Tsetse Flies ◽  
Life Cycle Stages ◽  
3D Electron Microscopy ◽  
Cilia And Flagella ◽  
Multicellular Organisms

ABSTRACTMulticellular organisms assemble cilia and flagella of precise lengths differing from one cell to another, yet little is known about the mechanisms governing these differences. Similarly, protists assemble flagella of different lengths according to the stage of their life cycle. Trypanosoma brucei assembles flagella of 3 to 30 µm during its development in the tsetse fly. This provides an opportunity to examine how cells naturally modulate organelle length. Flagella are constructed by addition of new blocks at their distal end via intraflagellar transport (IFT). Immunofluorescence assays, 3D electron microscopy and live-cell imaging revealed that IFT was present in all T. brucei life cycle stages. IFT proteins are concentrated at the base, and IFT trains are located along doublets 3–4 and 7–8 and travel bidirectionally in the flagellum. Quantitative analysis demonstrated that the total amount of flagellar IFT proteins correlates with the length of the flagellum. Surprisingly, the shortest flagellum exhibited a supplementary large amount of dynamic IFT material at its distal end. The contribution of IFT and other factors to the regulation of flagellum length is discussed.

scholarly journals Positional Dynamics and Glycosomal Recruitment of Developmental Regulators during Trypanosome Differentiation

mBio ◽  
2019 ◽  
Vol 10 (4) ◽  
Author(s):  
Balázs Szöőr ◽  
Dorina V. Simon ◽  
Federico Rojas ◽  
Julie Young ◽  
Derrick R. Robinson ◽  
...  
Keyword(s):  
Life Cycle ◽  
Trypanosoma Brucei ◽  
Tyrosine Phosphatase ◽  
Tsetse Fly ◽  
Sub Saharan Africa ◽  
Metabolic Adaptation ◽  
Tsetse Flies ◽  
Content Type ◽  
African Trypanosomes ◽  
Sub Saharan

ABSTRACT Glycosomes are peroxisome-related organelles that compartmentalize the glycolytic enzymes in kinetoplastid parasites. These organelles are developmentally regulated in their number and composition, allowing metabolic adaptation to the parasite’s needs in the blood of mammalian hosts or within their arthropod vector. A protein phosphatase cascade regulates differentiation between parasite developmental forms, comprising a tyrosine phosphatase, Trypanosoma brucei PTP1 (TbPTP1), which dephosphorylates and inhibits a serine threonine phosphatase, TbPIP39, which promotes differentiation. When TbPTP1 is inactivated, TbPIP39 is activated and during differentiation becomes located in glycosomes. Here we have tracked TbPIP39 recruitment to glycosomes during differentiation from bloodstream “stumpy” forms to procyclic forms. Detailed microscopy and live-cell imaging during the synchronous transition between life cycle stages revealed that in stumpy forms, TbPIP39 is located at a periflagellar pocket site closely associated with TbVAP, which defines the flagellar pocket endoplasmic reticulum. TbPTP1 is also located at the same site in stumpy forms, as is REG9.1, a regulator of stumpy-enriched mRNAs. This site provides a molecular node for the interaction between TbPTP1 and TbPIP39. Within 30 min of the initiation of differentiation, TbPIP39 relocates to glycosomes, whereas TbPTP1 disperses to the cytosol. Overall, the study identifies a “stumpy regulatory nexus” (STuRN) that coordinates the molecular components of life cycle signaling and glycosomal development during transmission of Trypanosoma brucei. IMPORTANCE African trypanosomes are parasites of sub-Saharan Africa responsible for both human and animal disease. The parasites are transmitted by tsetse flies, and completion of their life cycle involves progression through several development steps. The initiation of differentiation between blood and tsetse fly forms is signaled by a phosphatase cascade, ultimately trafficked into peroxisome-related organelles called glycosomes that are unique to this group of organisms. Glycosomes undergo substantial remodeling of their composition and function during the differentiation step, but how this is regulated is not understood. Here we identify a cytological site where the signaling molecules controlling differentiation converge before the dispersal of one of them into glycosomes. In combination, the study provides the first insight into the spatial coordination of signaling pathway components in trypanosomes as they undergo cell-type differentiation.

scholarly journals Timing and original features of flagellum assembly in trypanosomes during development in the tsetse fly

2019 ◽  
Author(s):  
Moara Lemos ◽  
Adeline Mallet ◽  
Eloïse Bertiaux ◽  
Albane Imbert ◽  
Brice Rotureau ◽  
...  
Keyword(s):  
Electron Microscopy ◽  
Life Cycle ◽  
Trypanosoma Brucei ◽  
Tsetse Fly ◽  
The Body ◽  
Complex Life Cycle ◽  
Tsetse Flies ◽  
Molecular Evidence ◽  
Morphological Development ◽  
Sequence Of Events

AbstractTrypanosoma brucei exhibits a complex life cycle alternating between tsetse flies and mammalian hosts. When parasites infect the fly, cells differentiate to adapt to life in various tissues, which is accompanied by drastic morphological and biochemical modifications especially in the proventriculus. This key step represents a bottleneck for salivary gland infection. Here we monitored flagellum assembly in trypanosomes during differentiation from the trypomastigote to the epimastigote stage, i.e. when the nucleus migrates to the posterior end of the cell. Three-dimensional electron microscopy (Focused Ion Bean Scanning Electron Microscopy, FIB-SEM) and immunofluorescence assays provided structural and molecular evidence that the new flagellum is assembled while the nucleus migrates towards the posterior region of the body. Two major differences with well known procyclic cells are reported. First, growth of the new flagellum begins when the associated basal body is found in a posterior position relative to the mature one. Second, the new flagellum acquires its own flagellar pocket before rotating on the left side of the anterior-posterior axis. FIB-SEM revealed the presence of a structure connecting the new and mature flagellum and serial sectioning confirmed morphological similarities with the flagella connector of procyclic cells. We discuss potential function of the flagella connector in trypanosomes from the proventriculus. These findings show that T. brucei finely modulates its cytoskeletal components to generate highly variable morphologies.Author SummaryTrypanosoma brucei is a flagellated parasitic protist that causes human African trypanosomiasis, or sleeping sickness and that is transmitted by the bite of tsetse flies. The complex life cycle of T. brucei inside the tsetse digestive tract requires adaptation to specific organs and follow a strictly defined order. It is marked by morphological modifications in cell shape and size, as well organelle positioning. In the proventriculus of tsetse flies, T. brucei undergoes a unique asymmetric division leading to two very different daughter cells: one with a short and one with a long flagellum. This organelle is crucial for the trypanosome life cycle as it is involved in motility, adhesion and morphogenesis. Here we investigated flagellum assembly using molecular and 3D Electron Microscopy approaches revealing that flagellum construction in proventricular trypanosomes is concomitant with parasite differentiation. During flagellum growth, the new flagellum is connected to the mature one and rotates around the mature one after its emergence at the cell surface. The sequence of events is different from what is observed in the well-studied procyclic stage in culture revealing different processes governing morphological development. These results highlight the importance to study pathogen development in their natural environment.

scholarly journals Positional dynamics and glycosomal recruitment of developmental regulators during trypanosome differentiation

2019 ◽  
Author(s):  
Balázs Szöőr ◽  
Dorina V. Simon ◽  
Federico Rojas ◽  
Julie Young ◽  
Derrick R. Robinson ◽  
...  
Keyword(s):  
Life Cycle ◽  
Tyrosine Phosphatase ◽  
Sub Saharan Africa ◽  
Metabolic Adaptation ◽  
Tsetse Flies ◽  
African Trypanosomes ◽  
Signalling Molecules ◽  
Life Cycle Stages ◽  
Sub Saharan ◽  
And Function

AbstractGlycosomes are peroxisome-related organelles that compartmentalise the glycolytic enzymes in kinetoplastid parasites. These organelles are developmentally regulated in their number and composition, allowing metabolic adaptation to the parasite’s needs in the blood of mammalian hosts or within their arthropod vector. A protein phosphatase cascade regulates differentiation between parasite developmental forms, comprising a tyrosine phosphatase, TbPTP1, that dephosphorylates and inhibits a serine threonine phosphatase TbPIP39 that promotes differentiation. When TbPTP1 is inactivated, TbPIP39 is activated and during differentiation becomes located in glycosomes. Here we have tracked TbPIP39 recruitment to glycosomes during differentiation from bloodstream stumpy forms to procyclic forms. Detailed microscopy and live cell imaging during the synchronous transition between life cycle stages revealed that in stumpy forms, TbPIP39 is located at a periflagellar pocket site closely associated with TbVAP, that defines the flagellar pocket endoplasmic reticulum. TbPTP1 is also located at the same site in stumpy forms, as is REG9.1, a regulator of stumpy-enriched mRNAs. This site provides a molecular node for the interaction between TbPTP1 and TbPIP39. Within 30 minutes of the initiation of differentiation TbPIP39 relocates to glycosomes whereas TbPTP1 disperses to the cytosol. Overall, the study identifies a ‘stumpy regulatory nexus’ (STuRN) that co-ordinates the molecular components of life cycle signalling and glycosomal development during transmission ofTrypanosoma brucei.ImportanceAfrican trypanosomes are parasites of sub-Saharan Africa responsible for both human and animal disease. The parasites are transmitted by tsetse flies and completion of their life cycle involves progression through several development steps. The initiation of differentiation between blood and tsetse forms is signalled by a phosphatase cascade, ultimately trafficked into peroxisome-related organelles called glycosomes that are unique to this group of organisms. Glycosomes undergo substantial remodelling of their composition and function during the differentiation step but how this is regulated is not understood. Here we identify a cytological site where the signalling molecules controlling differentiation converge before the dispersal of one of them into glycosomes. This coincides with a specialised ER site that may contribute to glycosome developmental biogenesis or regeneration. In combination, the study provides the first insight into the spatial co-ordination of signalling pathway components in trypanosomes as they undergo cell-type differentiation.

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.

Autonomy and integration in complex parasite life cycles

Parasitology ◽  
2016 ◽  
Vol 143 (14) ◽  
pp. 1824-1846 ◽  
Author(s):  
DANIEL P. BENESH
Keyword(s):  
Life Cycle ◽  
Holistic Approach ◽  
Life Cycles ◽  
Complex Life Cycle ◽  
Functional Specialization ◽  
Life Stages ◽  
Free Living ◽  
New Host ◽  
Complex Life Cycles ◽  
Life Cycle Stages

SUMMARYComplex life cycles are common in free-living and parasitic organisms alike. The adaptive decoupling hypothesis postulates that separate life cycle stages have a degree of developmental and genetic autonomy, allowing them to be independently optimized for dissimilar, competing tasks. That is, complex life cycles evolved to facilitate functional specialization. Here, I review the connections between the different stages in parasite life cycles. I first examine evolutionary connections between life stages, such as the genetic coupling of parasite performance in consecutive hosts, the interspecific correlations between traits expressed in different hosts, and the developmental and functional obstacles to stage loss. Then, I evaluate how environmental factors link life stages through carryover effects, where stressful larval conditions impact parasites even after transmission to a new host. There is evidence for both autonomy and integration across stages, so the relevant question becomes how integrated are parasite life cycles and through what mechanisms? By highlighting how genetics, development, selection and the environment can lead to interdependencies among successive life stages, I wish to promote a holistic approach to studying complex life cycle parasites and emphasize that what happens in one stage is potentially highly relevant for later stages.

scholarly journals Probing Plasmodium falciparum sexual commitment at the single-cell level

2018 ◽  
Vol 3 ◽  
pp. 70 ◽  
Author(s):  
Nicolas M.B. Brancucci ◽  
Mariana De Niz ◽  
Timothy J. Straub ◽  
Deepali Ravel ◽  
Lauriane Sollelis ◽  
...  
Keyword(s):  
Plasmodium Falciparum ◽  
Life Cycle ◽  
Single Cell ◽  
Transcriptional Profiling ◽  
Quantitative Imaging ◽  
Complex Life Cycle ◽  
Major Transitions ◽  
Transcriptional Signature ◽  
Life Cycle Stages ◽  
Parasite Populations

Background: Malaria parasites go through major transitions during their complex life cycle, yet the underlying differentiation pathways remain obscure. Here we apply single cell transcriptomics to unravel the program inducing sexual differentiation in Plasmodium falciparum. Parasites have to make this essential life-cycle decision in preparation for human-to-mosquito transmission. Methods: By combining transcriptional profiling with quantitative imaging and genetics, we defined a transcriptional signature in sexually committed cells. Results: We found this transcriptional signature to be distinct from general changes in parasite metabolism that can be observed in response to commitment-inducing conditions. Conclusions: This proof-of-concept study provides a template to capture transcriptional diversity in parasite populations containing complex mixtures of different life-cycle stages and developmental programs, with important implications for our understanding of parasite biology and the ongoing malaria elimination campaign.

scholarly journals Viviparity and habitat restrictions may influence the evolution of male reproductive genes in tsetse fly (Glossina) species

BMC Biology ◽  
2021 ◽  
Vol 19 (1) ◽  
Author(s):  
Grazia Savini ◽  
Francesca Scolari ◽  
Lino Ometto ◽  
Omar Rota-Stabelli ◽  
Davide Carraretto ◽  
...  
Keyword(s):  
Reproductive Behavior ◽  
Selective Pressure ◽  
Demographic History ◽  
Reproductive Rate ◽  
Tsetse Fly ◽  
Sub Saharan Africa ◽  
Comparative Genomic ◽  
Tsetse Flies ◽  
African Trypanosomes ◽  
Reproductive Genes

Abstract Background Glossina species (tsetse flies), the sole vectors of African trypanosomes, maintained along their long evolutionary history a unique reproductive strategy, adenotrophic viviparity. Viviparity reduces their reproductive rate and, as such, imposes strong selective pressures on males for reproductive success. These species live in sub-Saharan Africa, where the distributions of the main sub-genera Fusca, Morsitans, and Palpalis are restricted to forest, savannah, and riverine habitats, respectively. Here we aim at identifying the evolutionary patterns of the male reproductive genes of six species belonging to these three main sub-genera. We then interpreted the different patterns we found across the species in the light of viviparity and the specific habitat restrictions, which are known to shape reproductive behavior. Results We used a comparative genomic approach to build consensus evolutionary trees that portray the selective pressure acting on the male reproductive genes in these lineages. Such trees reflect the long and divergent demographic history that led to an allopatric distribution of the Fusca, Morsitans, and Palpalis species groups. A dataset of over 1700 male reproductive genes remained conserved over the long evolutionary time scale (estimated at 26.7 million years) across the genomes of the six species. We suggest that this conservation may result from strong functional selective pressure on the male imposed by viviparity. It is noteworthy that more than half of these conserved genes are novel sequences that are unique to the Glossina genus and are candidates for selection in the different lineages. Conclusions Tsetse flies represent a model to interpret the evolution and differentiation of male reproductive biology under different, but complementary, perspectives. In the light of viviparity, we must take into account that these genes are constrained by a post-fertilization arena for genomic conflicts created by viviparity and absent in ovipositing species. This constraint implies a continuous antagonistic co-evolution between the parental genomes, thus accelerating inter-population post-zygotic isolation and, ultimately, favoring speciation. Ecological restrictions that affect reproductive behavior may further shape such antagonistic co-evolution.

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