H. Ulrich Göringer scite author profile

RNA editing within the mitochondria of African trypanosomes is characterized by the insertion and deletion of uridylate residues into otherwise incomplete primary transcripts. The reaction takes place in a high molecular mass ribonucleoprotein (RNP) complex of uncertain composition. Furthermore, factors that interact with the RNP complex during the reaction are by and large unknown. Here we present evidence for an editing-related biochemical activity of the gRNA-binding protein gBP21. Using recombinant gBP21 preparations, we show that the protein stimulates the annealing of gRNAs to cognate pre-mRNAs in vitro. This represents the presumed first step of the editing reaction. Kinetic data establish an enhancement of the second order rate constant for the gRNA- pre-mRNA interaction. gBP21-mediated annealing is not exclusive for RNA editing substrates since complementary RNAs, unrelated to the editing process, can also be hybridized. The gBP21-dependent RNA annealing activity was identified in mitochondrial extracts of trypanosomes and can be inhibited by immunoprecipitation of the polypeptide. The data suggest a factor-like contribution of gBP21 to the RNA editing process by accelerating the rate of gRNA-pre-mRNA anchor formation.

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Combinatorial selection of high affinity RNA ligands to live African trypanosomes

Homann

Göringer

1999

Nucleic Acids Research

175

129

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African trypanosomiasis is a parasitic disease caused by a specific class of protozoan organisms. The best-studied representative of that group is Trypanosoma brucei which is transmitted by tsetse flies and multiplies in the blood of many mammals. Trypanosomes evade the immune system by altering their surface structure which is dominated by a layer of a variant surface glycoprotein (VSG). Although invariant surface proteins exist, they are inaccessible to the humoral immune response. Using a combinatorial selection method in conjunction with live trypanosomes as the binding target, we show that short RNA ligands (aptamers) for constant surface components can be isolated. We describe the selection of three classes of RNA aptamers that crosslink to a single 42 kDa protein located within the flagellar pocket of the parasite. The RNAs associate rapidly and with high affinity. They do not discriminate between two different trypanosome VSG variant strains and, furthermore, are able to bind to other trypanosome strains not used in the selection protocol. Thus, the aptamers have the potential to function as markers on the surface of the extracellular parasite and as such they might be modified to function as novel drugs against African trypanosomiasis.

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Lexis and Grammar of Mitochondrial RNA Processing in Trypanosomes

Aphasizheva¹,

Alfonzo²,

Carnes³

et al. 2020

Trends in Parasitology

126

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TbMP42, a Protein Component of the RNA Editing Complex in African Trypanosomes, Has Endo-Exoribonuclease Activity

Brecht

Niemann²,

Schlüter

et al. 2005

Molecular Cell

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RNA editing in trypanosomatids is catalyzed by a high molecular mass RNP complex, which is only partially characterized. TbMP42 is a 42 kDa protein of unknown function that copurifies with the editing complex. The polypeptide is characterized by two Zn fingers and a potential barrel structure/OB-fold at its C terminus. Using recombinant TbMP42, we show that the protein can bind to dsRNA and dsDNA but fails to recognize DNA/RNA hybrids. rTbMP42 degrades ssRNA by a 3' to 5' exoribonuclease activity. In addition, rTbMP42 has endoribonuclease activity, which preferentially hydrolyzes non-base-paired uridylate-containing sequences. Gene silencing of TbMP42 inhibits cell growth and is ultimately lethal to the parasite. Mitochondrial extracts from TbMP42-minus trypanosomes have only residual RNA editing activity and strongly reduced endo-exoribonuclease activity. However, all three activities can be restored by the addition of rTbMP42. Together, the data suggest that TbMP42 contributes both endo- and exoribonuclease activity to the editing reaction cycle.

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Snapshots of the RNA editing machine in trypanosomes captured at different assembly stages in vivo

Golas

Böhm

Sander

et al. 2009

EMBO J

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Mitochondrial pre-messenger RNAs in kinetoplastid protozoa are substrates of uridylate-specific RNA editing. RNA editing converts non-functional pre-mRNAs into translatable molecules and can generate protein diversity by alternative editing. Although several editing complexes have been described, their structure and relationship is unknown. Here, we report the isolation of functionally active RNA editing complexes by a multistep purification procedure. We show that the endogenous isolates contain two subpopulations of B20S and B35-40S and present the three-dimensional structures of both complexes by electron microscopy. The B35-40S complexes consist of a platform density packed against a semispherical element. The B20S complexes are composed of two subdomains connected by an interface. The two particles are structurally related, and we show that RNA binding is a main determinant for the interconversion of the two complexes. The B20S editosomes contain an RNA-binding site, which binds gRNA, pre-mRNA and gRNA/pre-mRNA hybrid molecules with nanomolar affinity. Variability analysis indicates that subsets of complexes lack or possess additional domains, suggesting binding sites for components. Together, a picture of the RNA editing machinery is provided.

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