An Alternative Strategy for Trypanosome Survival in the Mammalian Bloodstream Revealed through Genome and Transcriptome Analysis of the Ubiquitous Bovine Parasite Trypanosoma (Megatrypanum) theileri

Kelly, Steven L.; Ivens, Alasdair; Mott, G. Adam; O’Neill, Ellis C.; Emms, David; Macleod, Olivia J. S.; Voorheis, Paul; Clark, Matthew D.; Matthews, Jacqueline B.; Matthews, Keith R.; Carrington, Mark

doi:10.1093/gbe/evx152

Cited by 31 publications

(71 citation statements)

References 107 publications

(122 reference statements)

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“…To compare CIFs between TriTrypDB genomes and humans and to have sufficient data to estimate CIFs, we defined eight phylogenetic clades for 40 of the 46 trypanosome genomes as shown in Table 1. These clades were based on a composite of phylogenetic results in the literature [44-47] and CIFs were subsequently analyzed independently by clade. We removed two incomplete genomes from analysis, T. rangeli SC58 and T. cruzi CLBrenner that had fewer than half the number of tRNA genes identified in any other genome.…”

Section: Methodsmentioning

confidence: 99%

Targeting tRNA-Synthetase Interactions towards Novel Therapeutic Discovery Against Eukaryotic Pathogens

Kelly

Hadi-Nezhad

Liu

et al. 2019

Preprint

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43The development of chemotherapies against eukaryotic pathogens is especially 44 challenging because of both the evolutionary conservation of drug targets between host 45 and parasite, and the evolution of strain-dependent drug resistance. There is a strong 46 need for new nontoxic drugs with broad-spectrum activity against trypanosome 47 parasites such as Leishmania and Trypanosoma. A relatively untested approach is to 48 target macromolecular interactions in parasites rather than small molecular interactions, 49 under the hypothesis that the features specifying macromolecular interactions diverge 50 more rapidly through coevolution. We computed tRNA Class-Informative Features in 51 humans and eight clades of trypanosomes, identifying parasite-specific informative 52 features (including base-pairs and base mis-pairs) that are broadly conserved over 53 approximately 250 million years of trypanosome evolution. Validating these 54observations, we demonstrated biochemically that tRNA:aminoacyl-tRNA synthetase 55 interactions are a promising target for anti-trypanosomal drug discovery. From a marine 56 natural products extract library, we identified several fractions with inhibitory activity 57 toward Leishmania major alanyl-tRNA synthetase (AlaRS) but no activity against the 58 human homolog. These marine natural products extracts showed cross-reactivity 59 towards Trypanosoma cruzi AlaRS indicating the broad-spectrum potential of our 60 network predictions. These findings support a systems biology model in which 61 combination chemotherapies that target multiple tRNA-synthetase interactions should 62 be comparatively less prone to the emergence of resistance than conventional single 63 drug therapies. 64 65 Author Summary 66Trypanosome parasites pose a significant health risk worldwide. Conventional drug 67 development strategies have proven challenging given the high conservation between 68 humans and pathogens, with off-target toxicity being a common problem. Protein 69 synthesis inhibitors have historically been an attractive target for antimicrobial discovery 70 against bacteria, and more recently for eukaryotic pathogens. Here we propose that 71 exploiting pathogen-specific tRNA-synthetase interactions offers the potential for highly 72 targeted drug discovery. To this end, we improved tRNA gene annotations in 73 trypanosome genomes, identified functionally informative trypanosome-specific tRNA 74 features, and showed that these features are highly conserved over approximately 250 75 million years of trypanosome evolution. Highlighting the species-specific and broad-76 spectrum potential of our approach, we identified natural product inhibitors against the 77 parasite translational machinery that have no effect on the homologous human enzyme. 78 79 nontoxic drugs with broad-spectrum activity against different species of Leishmania and 89 other trypanosomes [6,7]. 90 Given their essential role in protein synthesis, aminoacyl-tRNA synthetases 91 (aaRSs) have been an attractive target for antimicrobial ...

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Section: Methodsmentioning

confidence: 99%

Targeting tRNA-Synthetase Interactions towards Novel Therapeutic Discovery Against Eukaryotic Pathogens

Kelly

Hadi-Nezhad

Liu

et al. 2019

Preprint

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“…The following proteomes were inputted into the Orthofinder script; Trypanosoma brucei brucei 927 v5.1 (Berriman et al, 2005), Trypanosoma brucei gambiense DAL972 v3 (Jackson et al ., 2010), Trypanosoma congolense IL3000 (Jackson et al ., 2012), Trypanosoma cruzi (CL Brener) (El-Sayed et al ., 2005), Trypanosoma evansi STIB805 (Carnes et al ., 2015), Trypanosoma grayi ANR4 v1 (Kelly et al ., 2015), Trypanosoma rangeli SC_58 v1 (Stoco et al ., 2014), Trypanosoma theileri Edinburgh (Kelly et al ., 2017), Trypanosoma vivax Y486 (Jackson et al ., 2012), Leishmania braziliensis M2903 (Peacock et al ., 2007), Leishmania donovani BPK282 v1 (Downing et al ., 2011), Leishmania infantum JPCM5 (Peacock et al ., 2007), Leishmania major Friedlin v6 (Ivens et al ., 2005), Leptomonas pyrrhocoris ASM129339v1 (Flegontov et al ., 2016), Leptomonas seymori ASM129953v1 (Kraeva et al ., 2015), Crithidia bombi (Schmid-Hempel et al ., 2018), Crithidia expoeki (Schmid-Hempel et al ., 2018), Crithidia fasciculata v14.0 (Runkel et al ., 2014), Angomonas deanei (Motta et al ., 2013), Phytomonas FM1 (Porcel et al ., 2014) and Bodo saltans v3 (Jackson et al ., 2008). Where possible the above sequences were obtained from TriTrypDB v41 (Aslett et al ., 2010).…”

Section: Methodsmentioning

confidence: 99%

Transcriptional and genomic parallels between the monoxenous parasiteHerpetomonas muscarumandLeishmania

Sloan

Brooks

Otto

et al. 2019

Preprint

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Trypanosomatid parasites are causative agents of important human and animal diseases such as sleeping sickness and leishmaniasis. Most trypanosomatids are transmitted to their mammalian hosts by insects, often belonging to Diptera (or true flies). These are called dixenous trypanosomatids since they infect two different hosts, in contrast to those that infect just insects (monoxenous). However, it is still unclear whether dixenous and monoxenous trypanosomatids interact similarly with their insect host, as fly-monoxenous trypanosomatid interaction systems are rarely reported and under-studied – despite being common in nature. Here we present the genome of monoxenous trypanosomatid Herpetomonas muscarum and discuss its transcriptome during in vitro culture and during infection of its natural insect host Drosophila melanogaster. The H. muscarum genome is broadly syntenic with that of human parasite Leishmania major. We also found strong similarities between the H. muscarum transcriptome during fruit fly infection, and those of Leishmania during sand fly infections. Overall this suggests Drosophila-Herpetomonas is a suitable model for less accessible insect-trypanosomatid host-parasite systems such as sand fly-Leishmania. Author Summary Trypanosomes and Leishmania are parasites that cause serious Neglected Tropical Diseases (NTDs) in the world’s poorest people. Both of these are dixenous trypanosomatids, transmitted to humans and other mammals by biting flies. They are called dixenous as they can establish infections in two different types of hosts – insect vectors and mammals. In contrast, monoxenous trypanosomatids usually only infect insects. Despite establishment in the insect’s midgut being key to transmission of NTDs, events during early establishment inside the insect are still unclear in both dixenous and monoxenous parasites. Here, we study the interaction between a model insect – the fruit fly Drosophila melanogaster – and its natural monoxenous trypanosomatid parasite Herpetomonas muscarum. We show that both the genome of this parasite, and gene regulation at early stages of infection have strong parallels with Leishmania. This work has begun to identify evolutionarily conserved aspects of the process by which trypanosomatids establish in insects, thus potentially highlighting key checkpoints necessary for transmission of dixenous parasites. In turn, this might inform new strategies to control trypanosomatid NTDs.

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“…For instance, T. cruzi has a complex glycocalyx composed of multiple monomeric GPI‐anchored proteins and free GPI lipids, perhaps reflecting the fact that T. cruzi is a mostly intracellular parasite that is only transiently exposed to host immunity . However, this may be overly simplistic as T. theileri , which is more closely related to T. cruzi , is modeled to have a similarly complex glycocalyx, yet is exclusively an extracellular parasite in the bovine host . That T. theileri also establishes long‐term infections indicates there are strategic alternatives to the paradigm of antigenic variation seen in African trypanosomes.…”

Section: Chicken or Egg: How Vsg Function Impacts Vsg Structurementioning

confidence: 99%

“…Already from the available genomic and transcriptomic data it is clear that both species differ significantly in their approach to antigenic variation. T. vivax diverged closer to the evolutionary root of the African trypanosomes, while the split of T. brucei and T. congolense is a more recent event . Illuminating this issue in these species will without doubt significantly impact our understanding of the evolution of antigenic variation in T. brucei .…”

Section: Whatever To Do?: Conclusion and Outlookmentioning

confidence: 99%

Evolution of Antigenic Variation in African Trypanosomes: Variant Surface Glycoprotein Expression, Structure, and Function

Bangs

2018

BioEssays

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The process of antigenic variation in parasitic African trypanosomes is a remarkable mechanism for outwitting the immune system of the mammalian host, but it requires a delicate balancing act for the monoallelic expression, folding and transport of a single variant surface glycoprotein (VSG). Only one of hundreds of VSG genes is expressed at time, and this from just one of ~15 dedicated expression sites. By switching expression of VSGs the parasite presents a continuously shifting antigenic facade leading to prolonged chronic infections lasting months to years. We have known the basics of VSG structure and switching for several decades, but recent studies have brought higher resolution to many aspects this process. New VSG structures, in silico modeling of infections, studies of VSG codon usage, and experimental ablation of VSG expression provide insights that inform how this remarkable system may have evolved.

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An Alternative Strategy for Trypanosome Survival in the Mammalian Bloodstream Revealed through Genome and Transcriptome Analysis of the Ubiquitous Bovine Parasite Trypanosoma (Megatrypanum) theileri

Cited by 31 publications

References 107 publications

Targeting tRNA-Synthetase Interactions towards Novel Therapeutic Discovery Against Eukaryotic Pathogens

Targeting tRNA-Synthetase Interactions towards Novel Therapeutic Discovery Against Eukaryotic Pathogens

Transcriptional and genomic parallels between the monoxenous parasiteHerpetomonas muscarumandLeishmania

Evolution of Antigenic Variation in African Trypanosomes: Variant Surface Glycoprotein Expression, Structure, and Function

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