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3. In situ structure of trypanosomal ATP synthase dimer reveals a unique arrangement of catalytic subunits

Author

Mühleip, Alexander W, Dewar, Caroline E, Schnaufer, Achim, Kühlbrandt, Werner, and Davies, Karen M

Subjects
1.1 Normal biological development and functioning, Underpinning research, Adenosine Triphosphate, Amino Acid Sequence, Animals, Catalysis, Catalytic Domain, Consensus Sequence, Dimerization, Euglena gracilis, Mitochondria, Models, Molecular, Protein Conformation, Proton-Translocating ATPases, Protozoan Proteins, Rotation, Sequence Alignment, Sequence Homology, Amino Acid, Trypanosoma brucei brucei, electron cryotomography, mitochondrial ATP synthase, rotary catalysis, subtomogram averaging, trypanosome
Abstract

We used electron cryotomography and subtomogram averaging to determine the in situ structures of mitochondrial ATP synthase dimers from two organisms belonging to the phylum euglenozoa: Trypanosoma brucei, a lethal human parasite, and Euglena gracilis, a photosynthetic protist. At a resolution of 32.5 Å and 27.5 Å, respectively, the two structures clearly exhibit a noncanonical F1 head, in which the catalytic (αβ)3 assembly forms a triangular pyramid rather than the pseudo-sixfold ring arrangement typical of all other ATP synthases investigated so far. Fitting of known X-ray structures reveals that this unusual geometry results from a phylum-specific cleavage of the α subunit, in which the C-terminal αC fragments are displaced by ∼20 Å and rotated by ∼30° from their expected positions. In this location, the αC fragment is unable to form the conserved catalytic interface that was thought to be essential for ATP synthesis, and cannot convert γ-subunit rotation into the conformational changes implicit in rotary catalysis. The new arrangement of catalytic subunits suggests that the mechanism of ATP generation by rotary ATPases is less strictly conserved than has been generally assumed. The ATP synthases of these organisms present a unique model system for discerning the individual contributions of the α and β subunits to the fundamental process of ATP synthesis.

Published
2017

4. What do kinetoplastids need a kinetoplast for? : life cycle progression of Trypanosoma brucei in the presence and absence of mitochondrial DNA

Author

Dewar, Caroline E., Schnaufer, Achim, and Matthews, Keith

Subjects
616.9, Trypanosoma brucei, kinetoplast, life cycle, trypanosomes
Abstract

The parasitic protist Trypanosoma brucei is the causative agent of human African trypanosomiasis. The parasite undergoes a complex life cycle involving stages within the mammalian bloodstream and its tsetse fly vector. The fundamental differences between energy metabolism in the procyclic insect form (PCF) and long slender bloodstream form (BSF) T. brucei involve a switch in the directionality of the F1Fo- ATPase. In PCF, the need for oxidative phosphorylation in low glucose conditions requires the enzyme to generate ATP. In the slender BSF, the enzyme uses ATP from glycolysis to drive proton pumping to maintain the essential mitochondrial membrane potential. Fo-ATPase subunit 6 (A6) is critical for proton translocation in either direction and is encoded in the mitochondrial DNA (kDNA). The parasite’s kDNA is therefore essential in the slender BSF, and also in PCF where it encodes multiple subunits of the respiratory chain complexes that constitute the oxidative phosphorylation pathway. Specific point mutations in the nuclearly encoded γ subunit of the mitochondrial F1Fo-ATPase allow survival in the absence of kDNA in the slender BSF T. brucei (Dean et al., 2013). These mutations, even in the heterozygous genotype, cause an increase in resistance to multiple drugs in vitro (Gould and Schnaufer, 2014). This thesis investigates two questions: (1) What is the molecular mechanism of compensation for kDNA loss? (2) Are kDNA and a functional FoF1-ATPase required for life cycle progression? Slender BSF T. brucei were generated expressing ATPase L262Pγ. The effects of this γ mutation and kDNA loss, respectively, on structure/function of the F1Fo- ATPase were probed. Cells expressing L262Pγ show decreased sensitivity to Fo inhibitor oligomycin compared to WT cells, suggesting that the L262Pγ mutation functionally uncouples the enzyme. The impact of the L262Pγ mutation on the structure of the enzyme was probed by high resolution clear native electrophoresis. This shows there are dramatic consequences to F1Fo structure in the presence of the L262Pγ mutation. The apparent selection for cells that no longer express intact F1Fo suggests that L262Pγ uncouples the enzyme, resulting in a lethal proton leak. Pleomorphic T. brucei with and without kDNA were also generated by expressing mutant γ in strain AnTat1.1 90:13. Differentiation studies demonstrate kDNA0 cells can differentiate to insect-transmissible stumpy forms. These cells show a decreased lifespan, suggesting a critical role for a kDNA-encoded product in the stumpy form. Tsetse fly infections show kDNA is indispensable for progression to the PCF. Unexpectedly, parasites homozygous for L262Pγ can establish a midgut infection, while they do not infect the salivary glands. Heterozygous parasites, on the other hand, can form animal-transmissible metacyclics in the salivary glands, providing a potential mechanism for spreading decreased sensitivity to multiple drugs.

Published
2016

10. The endoplasmic reticulum membrane protein complex localizes to the mitochondrial - endoplasmic reticulum interface and its subunits modulate phospholipid biosynthesis in Trypanosoma brucei

Author

Iyer, Advaitha, primary, Niemann, Moritz, additional, Serricchio, Mauro, additional, Dewar, Caroline E., additional, Oeljeklaus, Silke, additional, Farine, Luce, additional, Warscheid, Bettina, additional, Schneider, André, additional, and Bütikofer, Peter, additional

Published
2022
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11. Oxidative Phosphorylation Is Required for Powering Motility and Development of the Sleeping Sickness Parasite Trypanosoma brucei in the Tsetse Fly Vector

Author

Dewar, Caroline E., Casas Sanchez, Aitor, Dieme, Constentin, Crouzols, Aline, Haines, Lee, Acosta-Serrano, Alvaro, Rotureau, Brice, Schnaufer, Achim, and Hajduk, Stephen L.

Subjects
qw_51, qx_4, qx_650, wc_705, fungi, qu_450, qx_505, qw_55
Abstract

The single-celled parasite Trypanosoma brucei is transmitted by hematophagous tsetse flies. Life cycle progression from mammalian bloodstream form to tsetse midgut form and, subsequently, infective salivary gland form depends on complex developmental steps and migration within different fly tissues. As the parasite colonizes the glucose-poor insect midgut, ATP production is thought to depend on activation of mitochondrial amino acid catabolism via oxidative phosphorylation (OXPHOS). This process involves respiratory chain complexes and F1Fo-ATP synthase and requires protein subunits of these complexes that are encoded in the parasite's mitochondrial DNA (kDNA). Here, we show that progressive loss of kDNA-encoded functions correlates with a decreasing ability to initiate and complete development in the tsetse. First, parasites with a mutated F1Fo-ATP synthase with reduced capacity for OXPHOS can initiate differentiation from bloodstream to insect form, but they are unable to proliferate in vitro. Unexpectedly, these cells can still colonize the tsetse midgut. However, these parasites exhibit a motility defect and are severely impaired in colonizing or migrating to subsequent tsetse tissues. Second, parasites with a fully disrupted F1Fo-ATP synthase complex that is completely unable to produce ATP by OXPHOS can still differentiate to the first insect stage in vitro but die within a few days and cannot establish a midgut infection in vivo. Third, parasites lacking kDNA entirely can initiate differentiation but die soon after. Together, these scenarios suggest that efficient ATP production via OXPHOS is not essential for initial colonization of the tsetse vector but is required to power trypanosome migration within the fly.\ud \ud IMPORTANCE African trypanosomes cause disease in humans and their livestock and are transmitted by tsetse flies. The insect ingests these parasites with its blood meal, but to be transmitted to another mammal, the trypanosome must undergo complex development within the tsetse fly and migrate from the insect's gut to its salivary glands. Crucially, the parasite must switch from a sugar-based diet while in the mammal to a diet based primarily on amino acids when it develops in the insect. Here, we show that efficient energy production by an organelle called the mitochondrion is critical for the trypanosome's ability to swim and to migrate through the tsetse fly. Surprisingly, trypanosomes with impaired mitochondrial energy production are only mildly compromised in their ability to colonize the tsetse fly midgut. Our study adds a new perspective to the emerging view that infection of tsetse flies by trypanosomes is more complex than previously thought.

Published
2022

12. Characterisation of a highly diverged mitochondrial ATP synthase Fo subunit in Trypanosoma brucei

Author

Dewar, Caroline E, Oeljeklaus, Silke, Wenger, Christoph, Warscheid, Bettina, and Schneider, André

Subjects
540 Chemistry, 570 Life sciences, biology
Abstract

The mitochondrial F1Fo ATP synthase of the parasite Trypanosoma brucei has been previously studied in detail. This unusual enzyme switches direction in functionality during the life cycle of the parasite, acting as an ATP synthase in the insect stages, and as an ATPase to generate mitochondrial membrane potential in the mammalian bloodstream stages. Whereas the trypanosome F1 moiety is relatively highly conserved in structure and composition, the Fo subcomplex and the peripheral stalk have been shown to be more variable. Interestingly, a core subunit of the latter, the normally conserved subunit b, has been resistant to identification by sequence alignment or biochemical methods. Here we identified a 17 kDa mitochondrial protein of the inner membrane, Tb927.8.3070, that is essential for normal growth, efficient oxidative phosphorylation, and membrane potential maintenance. Pulldown experiments and native PAGE analysis indicated that the protein is both associated with the F1Fo ATP synthase, and integral to its assembly. In addition, its knockdown reduced the levels of Fo subunits, but not those of F1, and disturbed the cell cycle. Finally, analysis of structural homology using the HHpred algorithm showed that this protein has structural similarities to Fo subunit b of other species, indicating that this subunit may be a highly diverged form of the elusive subunit b.

Published
2022
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16. The endoplasmic reticulum membrane protein complex localizes to the mitochondrial - endoplasmic reticulum interface and its subunits modulate phospholipid biosynthesis in Trypanosoma brucei

Author

Iyer, Advaitha, primary, Niemann, Moritz, additional, Serricchio, Mauro, additional, Dewar, Caroline E., additional, Oeljeklaus, Silke, additional, Farine, Luce, additional, Warscheid, Bettina, additional, Schneider, André, additional, and Bütikofer, Peter, additional

Published
2021
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17. Mitochondrial DNA is critical for longevity and metabolism of transmission stage Trypanosoma brucei

Author

Dewar, Caroline E., MacGregor, Paula, Cooper, Sinclair, Gould, Matthew K., Matthews, Keith R., Savill, Nicholas J., Schnaufer, Achim, Dewar, Caroline E [0000-0002-0107-6985], MacGregor, Paula [0000-0003-0919-3745], Cooper, Sinclair [0000-0002-0371-1591], Savill, Nicholas J [0000-0002-9769-6168], Schnaufer, Achim [0000-0003-2132-5560], and Apollo - University of Cambridge Repository

Subjects
Life Cycles, Trypanosoma, Azides, QH301-705.5, Parasitic Life Cycles, Trypanosoma brucei gambiense, Trypanosoma brucei brucei, Bioenergetics, Biochemistry, Parasitic Cell Cycles, DNA, Mitochondrial, Host-Parasite Interactions, Mice, Parasitic cell cycles, parasitic diseases, Medicine and Health Sciences, Parasitic Diseases, Trypanosoma Brucei, Animals, Biology (General), Energy-Producing Organelles, Protozoans, DNA, Kinetoplast, Organisms, Chemical Compounds, Biology and Life Sciences, Eukaryota, Cell Differentiation, Cell Biology, RC581-607, Parasitic diseases, Parasitic Protozoans, Mitochondria, mitochondria, Chemistry, Kinetoplasts, Trypanosomiasis, African, Physical Sciences, Parasitology, Cellular Structures and Organelles, Immunologic diseases. Allergy, Research Article, Developmental Biology, Trypanosoma Brucei Gambiense
Abstract

The sleeping sickness parasite Trypanosoma brucei has a complex life cycle, alternating between a mammalian host and the tsetse fly vector. A tightly controlled developmental programme ensures parasite transmission between hosts as well as survival within them and involves strict regulation of mitochondrial activities. In the glucose-rich bloodstream, the replicative ‘slender’ stage is thought to produce ATP exclusively via glycolysis and uses the mitochondrial F1FO-ATP synthase as an ATP hydrolysis-driven proton pump to generate the mitochondrial membrane potential (ΔΨm). The ‘procyclic’ stage in the glucose-poor tsetse midgut depends on mitochondrial catabolism of amino acids for energy production, which involves oxidative phosphorylation with ATP production via the F1FO-ATP synthase. Both modes of the F1FO enzyme critically depend on FO subunit a, which is encoded in the parasite’s mitochondrial DNA (kinetoplast or kDNA). Comparatively little is known about mitochondrial function and the role of kDNA in non-replicative ‘stumpy’ bloodstream forms, a developmental stage essential for disease transmission. Here we show that the L262P mutation in the nuclear-encoded F1 subunit γ that permits survival of ‘slender’ bloodstream forms lacking kDNA (‘akinetoplastic’ forms), via FO-independent generation of ΔΨm, also permits their differentiation into stumpy forms. However, these akinetoplastic stumpy cells lack a ΔΨm and have a reduced lifespan in vitro and in mice, which significantly alters the within-host dynamics of the parasite. We further show that generation of ΔΨm in stumpy parasites and their ability to use α-ketoglutarate to sustain viability depend on F1-ATPase activity. Surprisingly, however, loss of ΔΨm does not reduce stumpy life span. We conclude that the L262P γ subunit mutation does not enable FO-independent generation of ΔΨm in stumpy cells, most likely as a consequence of mitochondrial ATP production in these cells. In addition, kDNA-encoded genes other than FO subunit a are important for stumpy form viability., Author summary African trypanosomes are single cellular eukaryotes transmitted by tsetse flies that cause important diseases in humans and their livestock. For survival these parasites depend on their mitochondrion, an organelle that has its own genome (‘mtDNA’) and that is traditionally viewed as the ‘power plant’ of cells, but that has other essential roles as well. Interfering with mtDNA is an important part of how some anti-trypanosomatid drugs work. Most mitochondrial research in trypanosomes in the past has focused on forms of the sleeping sickness parasite that proliferate in the mammalian bloodstream or in the insect midgut, as these can be readily cultured in the laboratory. As a consequence, relatively little is known about mitochondrial biology of the so-called ‘stumpy’ form, a non-replicative stage that is critical for transmission to tsetse flies. In this study we use a mouse infection model to show that a certain gene mutation permits formation of stumpy forms that lack mtDNA. However, without mtDNA these parasites have an altered mitochondrial metabolism and a reduced life span, which tells us that stumpy forms depend on additional mtDNA-encoded genes that are not required by the proliferative bloodstream form.

Published
2018
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19. Mitochondrial DNA is critical for longevity and metabolism of transmission stage Trypanosoma brucei

Author

Dewar, Caroline E, MacGregor, Paula, Cooper, Sinclair, Gould, Matthew K, Matthews, Keith R, Savill, Nicholas J, and Schnaufer, Achim

Subjects
Mice, Trypanosomiasis, African, DNA, Kinetoplast, parasitic diseases, Trypanosoma brucei brucei, Animals, DNA, Mitochondrial, 3. Good health, Host-Parasite Interactions
Abstract

The sleeping sickness parasite Trypanosoma brucei has a complex life cycle, alternating between a mammalian host and the tsetse fly vector. A tightly controlled developmental programme ensures parasite transmission between hosts as well as survival within them and involves strict regulation of mitochondrial activities. In the glucose-rich bloodstream, the replicative 'slender' stage is thought to produce ATP exclusively via glycolysis and uses the mitochondrial F1FO-ATP synthase as an ATP hydrolysis-driven proton pump to generate the mitochondrial membrane potential (ΔΨm). The 'procyclic' stage in the glucose-poor tsetse midgut depends on mitochondrial catabolism of amino acids for energy production, which involves oxidative phosphorylation with ATP production via the F1FO-ATP synthase. Both modes of the F1FO enzyme critically depend on FO subunit a, which is encoded in the parasite's mitochondrial DNA (kinetoplast or kDNA). Comparatively little is known about mitochondrial function and the role of kDNA in non-replicative 'stumpy' bloodstream forms, a developmental stage essential for disease transmission. Here we show that the L262P mutation in the nuclear-encoded F1 subunit γ that permits survival of 'slender' bloodstream forms lacking kDNA ('akinetoplastic' forms), via FO-independent generation of ΔΨm, also permits their differentiation into stumpy forms. However, these akinetoplastic stumpy cells lack a ΔΨm and have a reduced lifespan in vitro and in mice, which significantly alters the within-host dynamics of the parasite. We further show that generation of ΔΨm in stumpy parasites and their ability to use α-ketoglutarate to sustain viability depend on F1-ATPase activity. Surprisingly, however, loss of ΔΨm does not reduce stumpy life span. We conclude that the L262P γ subunit mutation does not enable FO-independent generation of ΔΨm in stumpy cells, most likely as a consequence of mitochondrial ATP production in these cells. In addition, kDNA-encoded genes other than FO subunit a are important for stumpy form viability.

20. A Msp1-containing complex removes orphaned proteins in the mitochondrial outer membrane of T. brucei .

Author

Gerber M, Suppanz I, Oeljeklaus S, Niemann M, Käser S, Warscheid B, Schneider A, and Dewar CE

Subjects
Membrane Proteins, Mitochondrial Membranes, Myositis, Inclusion Body, Frontotemporal Dementia, Protein Subunits, ATPases Associated with Diverse Cellular Activities genetics, Humans, Osteitis Deformans, Animals, Proteasome Endopeptidase Complex, Muscular Dystrophies, Limb-Girdle, Saccharomyces cerevisiae genetics, Proteomics
Abstract

The AAA-ATPase Msp1 extracts mislocalised outer membrane proteins and thus contributes to mitochondrial proteostasis. Using pulldown experiments, we show that trypanosomal Msp1 localises to both glycosomes and the mitochondrial outer membrane, where it forms a complex with four outer membrane proteins. The trypanosome-specific pATOM36 mediates complex assembly of α-helically anchored mitochondrial outer membrane proteins such as protein translocase subunits. Inhibition of their assembly triggers a pathway that results in the proteasomal digestion of unassembled substrates. Using inducible single, double, and triple RNAi cell lines combined with proteomic analyses, we demonstrate that not only Msp1 but also the trypanosomal homolog of the AAA-ATPase VCP are implicated in this quality control pathway. Moreover, in the absence of VCP three out of the four Msp1-interacting mitochondrial proteins are required for efficient proteasomal digestion of pATOM36 substrates, suggesting they act in concert with Msp1. pATOM36 is a functional analog of the yeast mitochondrial import complex complex and possibly of human mitochondrial animal-specific carrier homolog 2, suggesting that similar mitochondrial quality control pathways linked to Msp1 might also exist in yeast and humans., (© 2023 Gerber et al.)

Published
2023
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21. Oxidative Phosphorylation Is Required for Powering Motility and Development of the Sleeping Sickness Parasite Trypanosoma brucei in the Tsetse Fly Vector.

Author

Dewar CE, Casas-Sanchez A, Dieme C, Crouzols A, Haines LR, Acosta-Serrano Á, Rotureau B, and Schnaufer A

Subjects
Animals, Humans, DNA, Kinetoplast metabolism, Oxidative Phosphorylation, Mammals metabolism, Trypanosoma brucei brucei genetics, Tsetse Flies parasitology, Parasites genetics, Trypanosomiasis, African parasitology, Trypanosoma metabolism
Abstract

The single-celled parasite Trypanosoma brucei is transmitted by hematophagous tsetse flies. Life cycle progression from mammalian bloodstream form to tsetse midgut form and, subsequently, infective salivary gland form depends on complex developmental steps and migration within different fly tissues. As the parasite colonizes the glucose-poor insect midgut, ATP production is thought to depend on activation of mitochondrial amino acid catabolism via oxidative phosphorylation (OXPHOS). This process involves respiratory chain complexes and F 1 F o -ATP synthase and requires protein subunits of these complexes that are encoded in the parasite's mitochondrial DNA (kDNA). Here, we show that progressive loss of kDNA-encoded functions correlates with a decreasing ability to initiate and complete development in the tsetse. First, parasites with a mutated F 1 F o -ATP synthase with reduced capacity for OXPHOS can initiate differentiation from bloodstream to insect form, but they are unable to proliferate in vitro . Unexpectedly, these cells can still colonize the tsetse midgut. However, these parasites exhibit a motility defect and are severely impaired in colonizing or migrating to subsequent tsetse tissues. Second, parasites with a fully disrupted F 1 F o -ATP synthase complex that is completely unable to produce ATP by OXPHOS can still differentiate to the first insect stage in vitro but die within a few days and cannot establish a midgut infection in vivo . Third, parasites lacking kDNA entirely can initiate differentiation but die soon after. Together, these scenarios suggest that efficient ATP production via OXPHOS is not essential for initial colonization of the tsetse vector but is required to power trypanosome migration within the fly. IMPORTANCE African trypanosomes cause disease in humans and their livestock and are transmitted by tsetse flies. The insect ingests these parasites with its blood meal, but to be transmitted to another mammal, the trypanosome must undergo complex development within the tsetse fly and migrate from the insect's gut to its salivary glands. Crucially, the parasite must switch from a sugar-based diet while in the mammal to a diet based primarily on amino acids when it develops in the insect. Here, we show that efficient energy production by an organelle called the mitochondrion is critical for the trypanosome's ability to swim and to migrate through the tsetse fly. Surprisingly, trypanosomes with impaired mitochondrial energy production are only mildly compromised in their ability to colonize the tsetse fly midgut. Our study adds a new perspective to the emerging view that infection of tsetse flies by trypanosomes is more complex than previously thought.

Published
2022
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