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21 results on '"Shimogawa, Michelle M."'

1. FAP106 is an interaction hub for assembling microtubule inner proteins at the cilium inner junction

Author

Shimogawa, Michelle M, Wijono, Angeline S, Wang, Hui, Zhang, Jiayan, Sha, Jihui, Szombathy, Natasha, Vadakkan, Sabeeca, Pelayo, Paula, Jonnalagadda, Keya, Wohlschlegel, James, Zhou, Z Hong, and Hill, Kent L

Subjects
Biochemistry and Cell Biology, Biological Sciences, Infectious Diseases, Vector-Borne Diseases, Rare Diseases, 1.1 Normal biological development and functioning, 2.2 Factors relating to the physical environment, Infection, Good Health and Well Being, Cilia, Flagella, Microtubules, Acclimatization, Axoneme, Microtubule Proteins
Abstract

Motility of pathogenic protozoa depends on flagella (synonymous with cilia) with axonemes containing nine doublet microtubules (DMTs) and two singlet microtubules. Microtubule inner proteins (MIPs) within DMTs influence axoneme stability and motility and provide lineage-specific adaptations, but individual MIP functions and assembly mechanisms are mostly unknown. Here, we show in the sleeping sickness parasite Trypanosoma brucei, that FAP106, a conserved MIP at the DMT inner junction, is required for trypanosome motility and functions as a critical interaction hub, directing assembly of several conserved and lineage-specific MIPs. We use comparative cryogenic electron tomography (cryoET) and quantitative proteomics to identify MIP candidates. Using RNAi knockdown together with fitting of AlphaFold models into cryoET maps, we demonstrate that one of these candidates, MC8, is a trypanosome-specific MIP required for parasite motility. Our work advances understanding of MIP assembly mechanisms and identifies lineage-specific motility proteins that are attractive targets to consider for therapeutic intervention.

Published
2023

2. APEX2 Proximity Proteomics Resolves Flagellum Subdomains and Identifies Flagellum Tip-Specific Proteins in Trypanosoma brucei

Author

Vélez-Ramírez, Daniel E, Shimogawa, Michelle M, Ray, Sunayan S, Lopez, Andrew, Rayatpisheh, Shima, Langousis, Gerasimos, Gallagher-Jones, Marcus, Dean, Samuel, Wohlschlegel, James A, and Hill, Kent L

Subjects
Biochemistry and Cell Biology, Biological Sciences, Vector-Borne Diseases, Infectious Diseases, 2.2 Factors relating to the physical environment, Infection, Good Health and Well Being, DNA-(Apurinic or Apyrimidinic Site) Lyase, Endonucleases, Flagella, Humans, Multifunctional Enzymes, Proteome, Proteomics, Protozoan Proteins, Signal Transduction, Trypanosoma brucei brucei, Trypanosoma, signaling, flagella, cell signaling, Immunology, Microbiology
Abstract

Trypanosoma brucei is the protozoan parasite responsible for sleeping sickness, a lethal vector-borne disease. T. brucei has a single flagellum (cilium) that plays critical roles in transmission and pathogenesis. An emerging concept is that the flagellum is organized into subdomains, each having specialized composition and function. The overall flagellum proteome has been well studied, but a critical knowledge gap is the protein composition of individual subdomains. We have tested whether APEX-based proximity proteomics could be used to examine the protein composition of T. brucei flagellum subdomains. As APEX-based labeling has not previously been described in T. brucei, we first fused APEX2 to the DRC1 subunit of the nexin-dynein regulatory complex, a well-characterized axonemal complex. We found that DRC1-APEX2 directs flagellum-specific biotinylation, and purification of biotinylated proteins yields a DRC1 "proximity proteome" having good overlap with published proteomes obtained from purified axonemes. Having validated the use of APEX2 in T. brucei, we next attempted to distinguish flagellar subdomains by fusing APEX2 to a flagellar membrane protein that is restricted to the flagellum tip, AC1, and another one that is excluded from the tip, FS179. Fluorescence microscopy demonstrated subdomain-specific biotinylation, and principal-component analysis showed distinct profiles between AC1-APEX2 and FS179-APEX2. Comparing these two profiles allowed us to identify an AC1 proximity proteome that is enriched for tip proteins, including proteins involved in signaling. Our results demonstrate that APEX2-based proximity proteomics is effective in T. brucei and can be used to resolve the proteome composition of flagellum subdomains that cannot themselves be readily purified.IMPORTANCE Sleeping sickness is a neglected tropical disease caused by the protozoan parasite Trypanosoma brucei The disease disrupts the sleep-wake cycle, leading to coma and death if left untreated. T. brucei motility, transmission, and virulence depend on its flagellum (cilium), which consists of several different specialized subdomains. Given the essential and multifunctional role of the T. brucei flagellum, there is need for approaches that enable proteomic analysis of individual subdomains. Our work establishes that APEX2 proximity labeling can, indeed, be implemented in the biochemical environment of T. brucei and has allowed identification of proximity proteomes for different flagellar subdomains that cannot be purified. This capacity opens the possibility to study the composition and function of other compartments. We expect this approach may be extended to other eukaryotic pathogens and will enhance the utility of T. brucei as a model organism to study ciliopathies, heritable human diseases in which cilium function is impaired.

Published
2021

3. Parasite motility is critical for virulence of African trypanosomes.

Author

Shimogawa, Michelle M, Ray, Sunayan S, Kisalu, Neville, Zhang, Yibo, Geng, Quanjie, Ozcan, Aydogan, and Hill, Kent L

Subjects
Flagella, Animals, Mice, Inbred BALB C, Cattle, Mice, Trypanosoma brucei brucei, Trypanosomiasis, African, Mutation, Female, Inbred BALB C, Trypanosomiasis, African
Abstract

African trypanosomes, Trypanosoma brucei spp., are lethal pathogens that cause substantial human suffering and limit economic development in some of the world's most impoverished regions. The name Trypanosoma ("auger cell") derives from the parasite's distinctive motility, which is driven by a single flagellum. However, despite decades of study, a requirement for trypanosome motility in mammalian host infection has not been established. LC1 is a conserved dynein subunit required for flagellar motility. Prior studies with a conditional RNAi-based LC1 mutant, RNAi-K/R, revealed that parasites with defective motility could infect mice. However, RNAi-K/R retained residual expression of wild-type LC1 and residual motility, thus precluding definitive interpretation. To overcome these limitations, here we generate constitutive mutants in which both LC1 alleles are replaced with mutant versions. These double knock-in mutants show reduced motility compared to RNAi-K/R and are viable in culture, but are unable to maintain bloodstream infection in mice. The virulence defect is independent of infection route but dependent on an intact host immune system. By comparing different mutants, we also reveal a critical dependence on the LC1 N-terminus for motility and virulence. Our findings demonstrate that trypanosome motility is critical for establishment and maintenance of bloodstream infection, implicating dynein-dependent flagellar motility as a potential drug target.

Published
2018

4. Motility-based label-free detection of parasites in bodily fluids using holographic speckle analysis and deep learning

Author

Zhang, Yibo, Ceylan Koydemir, Hatice, Shimogawa, Michelle M, Yalcin, Sener, Guziak, Alexander, Liu, Tairan, Oguz, Ilker, Huang, Yujia, Bai, Bijie, Luo, Yilin, Luo, Yi, Wei, Zhensong, Wang, Hongda, Bianco, Vittorio, Zhang, Bohan, Nadkarni, Rohan, Hill, Kent, and Ozcan, Aydogan

Subjects
Atomic, Molecular and Optical Physics, Physical Sciences, Clinical Research, Prevention, Infectious Diseases, Vector-Borne Diseases, Bioengineering, 4.2 Evaluation of markers and technologies, Detection, screening and diagnosis, 4.1 Discovery and preclinical testing of markers and technologies, Infection, Good Health and Well Being, Optical Physics, Atomic, molecular and optical physics
Abstract

Parasitic infections constitute a major global public health issue. Existing screening methods that are based on manual microscopic examination often struggle to provide sufficient volumetric throughput and sensitivity to facilitate early diagnosis. Here, we demonstrate a motility-based label-free computational imaging platform to rapidly detect motile parasites in optically dense bodily fluids by utilizing the locomotion of the parasites as a specific biomarker and endogenous contrast mechanism. Based on this principle, a cost-effective and mobile instrument, which rapidly screens ~3.2 mL of fluid sample in three dimensions, was built to automatically detect and count motile microorganisms using their holographic time-lapse speckle patterns. We demonstrate the capabilities of our platform by detecting trypanosomes, which are motile protozoan parasites, with various species that cause deadly diseases affecting millions of people worldwide. Using a holographic speckle analysis algorithm combined with deep learning-based classification, we demonstrate sensitive and label-free detection of trypanosomes within spiked whole blood and artificial cerebrospinal fluid (CSF) samples, achieving a limit of detection of ten trypanosomes per mL of whole blood (~five-fold better than the current state-of-the-art parasitological method) and three trypanosomes per mL of CSF. We further demonstrate that this platform can be applied to detect other motile parasites by imaging Trichomonas vaginalis, the causative agent of trichomoniasis, which affects 275 million people worldwide. With its cost-effective, portable design and rapid screening time, this unique platform has the potential to be applied for sensitive and timely diagnosis of neglected tropical diseases caused by motile parasites and other parasitic infections in resource-limited regions.

Published
2018

6. Loss of the BBSome perturbs endocytic trafficking and disrupts virulence of Trypanosoma brucei

Author

Langousis, Gerasimos, Shimogawa, Michelle M, Saada, Edwin A, Vashisht, Ajay A, Spreafico, Roberto, Nager, Andrew R, Barshop, William D, Nachury, Maxence V, Wohlschlegel, James A, and Hill, Kent L

Subjects
Biochemistry and Cell Biology, Biological Sciences, Congenital Structural Anomalies, Pediatric, Rare Diseases, Intellectual and Developmental Disabilities (IDD), Infectious Diseases, Brain Disorders, Vector-Borne Diseases, 2.2 Factors relating to the physical environment, 1.1 Normal biological development and functioning, Generic health relevance, Infection, Good Health and Well Being, Animals, Bardet-Biedl Syndrome, Clathrin, Endocytosis, Flagella, Intracellular Membranes, Membrane Proteins, Mice, Parasites, Protein Binding, Protein Transport, Protozoan Proteins, Transport Vesicles, Trypanosoma brucei brucei, Virulence, BBSome, virulence, cilium, clathrin, ubiquitin
Abstract

Cilia (eukaryotic flagella) are present in diverse eukaryotic lineages and have essential motility and sensory functions. The cilium's capacity to sense and transduce extracellular signals depends on dynamic trafficking of ciliary membrane proteins. This trafficking is often mediated by the Bardet-Biedl Syndrome complex (BBSome), a protein complex for which the precise subcellular distribution and mechanisms of action are unclear. In humans, BBSome defects perturb ciliary membrane protein distribution and manifest clinically as Bardet-Biedl Syndrome. Cilia are also important in several parasites that cause tremendous human suffering worldwide, yet biology of the parasite BBSome remains largely unexplored. We examined BBSome functions in Trypanosoma brucei, a flagellated protozoan parasite that causes African sleeping sickness in humans. We report that T. brucei BBS proteins assemble into a BBSome that interacts with clathrin and is localized to membranes of the flagellar pocket and adjacent cytoplasmic vesicles. Using BBS gene knockouts and a mouse infection model, we show the T. brucei BBSome is dispensable for flagellar assembly, motility, bulk endocytosis, and cell viability but required for parasite virulence. Quantitative proteomics reveal alterations in the parasite surface proteome of BBSome mutants, suggesting that virulence defects are caused by failure to maintain fidelity of the host-parasite interface. Interestingly, among proteins altered are those with ubiquitination-dependent localization, and we find that the BBSome interacts with ubiquitin. Collectively, our data indicate that the BBSome facilitates endocytic sorting of select membrane proteins at the base of the cilium, illuminating BBSome roles at a critical host-pathogen interface and offering insights into BBSome molecular mechanisms.

Published
2016

7. Cell Surface Proteomics Provides Insight into Stage-Specific Remodeling of the Host-Parasite Interface in Trypanosoma brucei*

Author

Shimogawa, Michelle M, Saada, Edwin A, Vashisht, Ajay A, Barshop, William D, Wohlschlegel, James A, and Hill, Kent L

Subjects
Biochemistry and Cell Biology, Biological Sciences, Genetics, Infectious Diseases, Vector-Borne Diseases, Biotechnology, 2.2 Factors relating to the physical environment, Generic health relevance, Infection, Good Health and Well Being, Adaptation, Physiological, Animals, Cell Membrane, Databases, Protein, Host-Parasite Interactions, Humans, Life Cycle Stages, Multigene Family, Parasites, Proteome, Proteomics, Protozoan Proteins, Trypanosoma brucei brucei, Variant Surface Glycoproteins, Trypanosoma, Biochemistry & Molecular Biology
Abstract

African trypanosomes are devastating human and animal pathogens transmitted by tsetse flies between mammalian hosts. The trypanosome surface forms a critical host interface that is essential for sensing and adapting to diverse host environments. However, trypanosome surface protein composition and diversity remain largely unknown. Here, we use surface labeling, affinity purification, and proteomic analyses to describe cell surface proteomes from insect-stage and mammalian bloodstream-stage Trypanosoma brucei. The cell surface proteomes contain most previously characterized surface proteins. We additionally identify a substantial number of novel proteins, whose functions are unknown, indicating the parasite surface proteome is larger and more diverse than generally appreciated. We also show stage-specific expression for individual paralogs within several protein families, suggesting that fine-tuned remodeling of the parasite surface allows adaptation to diverse host environments, while still fulfilling universally essential cellular needs. Our surface proteome analyses complement existing transcriptomic, proteomic, and in silico analyses by highlighting proteins that are surface-exposed and thereby provide a major step forward in defining the host-parasite interface.

Published
2015

8. Insect Stage-Specific Receptor Adenylate Cyclases Are Localized to Distinct Subdomains of the Trypanosoma brucei Flagellar Membrane

Author

Saada, Edwin A, Kabututu, Z Pius, Lopez, Miguel, Shimogawa, Michelle M, Langousis, Gerasimos, Oberholzer, Michael, Riestra, Angelica, Jonsson, Zophonias O, Wohlschlegel, James A, and Hill, Kent L

Subjects
Biochemistry and Cell Biology, Biological Sciences, Vector-Borne Diseases, Infectious Diseases, 2.2 Factors relating to the physical environment, Infection, Adenylyl Cyclases, Animals, Cell Line, Flagella, Insecta, Life Cycle Stages, Protein Transport, Protozoan Proteins, RNA, Messenger, Trypanosoma brucei brucei, Immunology, Microbiology
Abstract

Increasing evidence indicates that the Trypanosoma brucei flagellum (synonymous with cilium) plays important roles in host-parasite interactions. Several studies have identified virulence factors and signaling proteins in the flagellar membrane of bloodstream-stage T. brucei, but less is known about flagellar membrane proteins in procyclic, insect-stage parasites. Here we report on the identification of several receptor-type flagellar adenylate cyclases (ACs) that are specifically upregulated in procyclic T. brucei parasites. Identification of insect stage-specific ACs is novel, as previously studied ACs were constitutively expressed or confined to bloodstream-stage parasites. We show that procyclic stage-specific ACs are glycosylated, surface-exposed proteins that dimerize and possess catalytic activity. We used gene-specific tags to examine the distribution of individual AC isoforms. All ACs examined localized to the flagellum. Notably, however, while some ACs were distributed along the length of the flagellum, others specifically localized to the flagellum tip. These are the first transmembrane domain proteins to be localized specifically at the flagellum tip in T. brucei, emphasizing that the flagellum membrane is organized into specific subdomains. Deletion analysis reveals that C-terminal sequences are critical for targeting ACs to the flagellum, and sequence comparisons suggest that differential subflagellar localization might be specified by isoform-specific C termini. Our combined results suggest insect stage-specific roles for a subset of flagellar adenylate cyclases and support a microdomain model for flagellar cyclic AMP (cAMP) signaling in T. brucei. In this model, cAMP production is compartmentalized through differential localization of individual ACs, thereby allowing diverse cellular responses to be controlled by a common signaling molecule.

Published
2014

9. FAP106 is an interaction hub required for assembly of conserved and lineage-specific microtubule inner proteins at the cilium inner junction

Author

Shimogawa, Michelle M., primary, Wijono, Angeline S., additional, Wang, Hui, additional, Zhang, Jiayan, additional, Sha, Jihui, additional, Szombathy, Natasha, additional, Vadakkan, Sabeeca, additional, Pelayo, Paula, additional, Jonnalagadda, Keya, additional, Wohlschlegel, James, additional, Zhou, Z. Hong, additional, and Hill, Kent L., additional

Published
2022
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10. FAP20 is required for flagellum assembly in Trypanosoma brucei

Author

Shimogawa, Michelle M., Jonnalagadda, Keya, and Hill, Kent L.

Abstract

Trypanosoma bruceiis a human and animal pathogen that depends on flagellar motility for transmission and infection. The trypanosome flagellum is built around a canonical “9+2” axoneme, containing nine doublet microtubules (DMTs) surrounding two singlet microtubules. Each DMT contains a 13-protofilament A-tubule and a 10-protofilament B-tubule, connected to the A-tubule by a conserved, non-tubulin inner junction (IJ) filament made up of alternating PACRG and FAP20 subunits. Here we investigate FAP20 in procyclic form T. brucei. A FAP20-NeonGreen fusion protein localized to the axoneme as expected. Surprisingly, FAP20knockdown led to a catastrophic failure in flagellum assembly and concomitant lethality. This differs from other organisms, where FAP20 is required for normal flagellum motility, but generally dispensable for flagellum assembly and viability. Transmission electron microscopy demonstrates failed flagellum assembly in FAP20 mutants is associated with a range of DMT defects and defective assembly of the paraflagellar rod, a lineage-specific flagellum filament that attaches to DMT 4-7 in trypanosomes. Our studies reveal a lineage-specific requirement for FAP20 in trypanosomes, offering insight into adaptations for flagellum stability and motility in these parasites and highlighting pathogen versus host differences that might be considered for therapeutic intervention in trypanosome diseases.

Published
2024
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11. APEX2 proximity proteomics resolves flagellum subdomains and identifies flagellum tip-specific proteins inTrypanosoma brucei

Author

Vélez-Ramírez, Daniel E., primary, Shimogawa, Michelle M., additional, Ray, Sunayan, additional, Lopez, Andrew, additional, Rayatpisheh, Shima, additional, Langousis, Gerasimos, additional, Gallagher-Jones, Marcus, additional, Dean, Samuel, additional, Wohlschlegel, James A., additional, and Hill, Kent L., additional

Published
2020
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12. High-Throughput and Label-Free Detection of Motile Parasites in Bodily Fluids Using Lensless Time-Resolved Speckle Imaging

Author

Zhang, Yibo, primary, Koydemir, Hatice Ceylan, additional, Shimogawa, Michelle M., additional, Yalcin, Sener, additional, Guziak, Alexander, additional, Liu, Tairan, additional, Oguz, Ilker, additional, Huang, Yujia, additional, Bai, Bijie, additional, Luo, Yilin, additional, Luo, Yi, additional, Wei, Zhensong, additional, Wang, Hongda, additional, Bianco, Vittorio, additional, Zhang, Bohan, additional, Nadkarni, Rohan, additional, Hill, Kent, additional, and Ozcan, Aydogan, additional

Published
2019
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15. Insect Stage-Specific Receptor Adenylate Cyclases Are Localized to Distinct Subdomains of the Trypanosoma brucei Flagellar Membrane

Author

Saada, Edwin A., primary, Kabututu, Z. Pius, additional, Lopez, Miguel, additional, Shimogawa, Michelle M., additional, Langousis, Gerasimos, additional, Oberholzer, Michael, additional, Riestra, Angelica, additional, Jonsson, Zophonias O., additional, Wohlschlegel, James A., additional, and Hill, Kent L., additional

Published
2014
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16. Independent Analysis of the Flagellum Surface and Matrix Proteomes Provides Insight into Flagellum Signaling in Mammalian-infectious Trypanosoma brucei

Author

Oberholzer, Michael, primary, Langousis, Gerasimos, additional, Nguyen, HoangKim T., additional, Saada, Edwin A., additional, Shimogawa, Michelle M., additional, Jonsson, Zophonias O., additional, Nguyen, Steven M., additional, Wohlschlegel, James A., additional, and Hill, Kent L., additional

Published
2011
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19. Mps1 Phosphorylation of Dam1 Couples Kinetochores to Microtubule Plus Ends at Metaphase

Author

Shimogawa, Michelle M., primary, Graczyk, Beth, additional, Gardner, Melissa K., additional, Francis, Susan E., additional, White, Erin A., additional, Ess, Michael, additional, Molk, Jeffrey N., additional, Ruse, Cristian, additional, Niessen, Sherry, additional, Yates, John R., additional, Muller, Eric G.D., additional, Bloom, Kerry, additional, Odde, David J., additional, and Davis, Trisha N., additional

Published
2006
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20. Insect Stage-Specific Receptor Adenylate Cyclases Are Localized to Distinct Subdomains of the Trypanosoma bruceiFlagellar Membrane

Author

Saada, Edwin A., Kabututu, Z. Pius, Lopez, Miguel, Shimogawa, Michelle M., Langousis, Gerasimos, Oberholzer, Michael, Riestra, Angelica, Jonsson, Zophonias O., Wohlschlegel, James A., and Hill, Kent L.

Abstract

ABSTRACTIncreasing evidence indicates that the Trypanosoma bruceiflagellum (synonymous with cilium) plays important roles in host-parasite interactions. Several studies have identified virulence factors and signaling proteins in the flagellar membrane of bloodstream-stage T. brucei, but less is known about flagellar membrane proteins in procyclic, insect-stage parasites. Here we report on the identification of several receptor-type flagellar adenylate cyclases (ACs) that are specifically upregulated in procyclic T. bruceiparasites. Identification of insect stage-specific ACs is novel, as previously studied ACs were constitutively expressed or confined to bloodstream-stage parasites. We show that procyclic stage-specific ACs are glycosylated, surface-exposed proteins that dimerize and possess catalytic activity. We used gene-specific tags to examine the distribution of individual AC isoforms. All ACs examined localized to the flagellum. Notably, however, while some ACs were distributed along the length of the flagellum, others specifically localized to the flagellum tip. These are the first transmembrane domain proteins to be localized specifically at the flagellum tip in T. brucei, emphasizing that the flagellum membrane is organized into specific subdomains. Deletion analysis reveals that C-terminal sequences are critical for targeting ACs to the flagellum, and sequence comparisons suggest that differential subflagellar localization might be specified by isoform-specific C termini. Our combined results suggest insect stage-specific roles for a subset of flagellar adenylate cyclases and support a microdomain model for flagellar cyclic AMP (cAMP) signaling in T. brucei. In this model, cAMP production is compartmentalized through differential localization of individual ACs, thereby allowing diverse cellular responses to be controlled by a common signaling molecule.

Published
2014
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21. FAP20 is required for flagellum assembly in Trypanosoma brucei .

Author

Shimogawa MM, Jonnalagadda K, and Hill KL

Abstract

Trypanosoma brucei is a human and animal pathogen that depends on flagellar motility for transmission and infection. The trypanosome flagellum is built around a canonical "9+2" axoneme, containing nine doublet microtubules (DMTs) surrounding two singlet microtubules. Each DMT contains a 13-protofilament A-tubule and a 10-protofilament B-tubule, connected to the A-tubule by a conserved, non-tubulin inner junction (IJ) filament made up of alternating PACRG and FAP20 subunits. Here we investigate FAP20 in procyclic form T. brucei . A FAP20-NeonGreen fusion protein localized to the axoneme as expected. Surprisingly, FAP20 knockdown led to a catastrophic failure in flagellum assembly and concomitant lethal cell division defect. This differs from other organisms, where FAP20 is required for normal flagellum motility, but generally dispensable for flagellum assembly and viability. Transmission electron microscopy demonstrates failed flagellum assembly in FAP20 mutants is associated with a range of DMT defects and defective assembly of the paraflagellar rod, a lineage-specific flagellum filament that attaches to DMT 4-7 in trypanosomes. Our studies reveal a lineage-specific requirement for FAP20 in trypanosomes, offering insight into adaptations for flagellum stability and motility in these parasites and highlighting pathogen versus host differences that might be considered for therapeutic intervention in trypanosome diseases.

Published
2024
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