Identification by UV cross-linking of oligo(U)-binding proteins in mitochondria of the insect trypanosomatid Crithidia fasciculata

Structure and function of the native and recombinant mitochondrial MRP1/MRP2 complex from Trypanosoma brucei

The mitochondrial RNA-binding proteins (MRP) 1 and 2 play a regulatory role in RNA editing and putative role(s) in RNA processing in Trypanosoma brucei. Here, we report the purification of a high molecular weight protein complex consisting solely of the MRP1 and MRP2 proteins from the mitochondrion of T. brucei. The MRP1/MRP2 complex natively purified from T. brucei and the one reconstituted in Escherichia coli in vivo bind guide (g) RNAs and pre-mRNAs with dissociation constants in the nanomolar range, and efficiently promote annealing of pre-mRNAs with their cognate gRNAs. In addition, the MRP1/MRP2 complex stimulates annealing between two non-cognate RNA molecules suggesting that along with the cognate duplexes, spuriously mismatched RNA hybrids may be formed at some rate in vivo. A mechanism of catalysed annealing of gRNA/pre-mRNA by the MRP1/MRP2 complex is proposed.

TbRGG1, an essential protein involved in kinetoplastid RNA metabolism that is associated with a novel multiprotein complex

The uridine insertion/deletion RNA editing of kinetoplastid mitochondrial transcripts is performed by complex machinery involving a number of proteins and multiple protein complexes. Here we describe the effect of silencing of TbRGG1 gene by RNA interference on RNA editing in procyclic stage of Trypanosoma brucei. TbRGG1 is an essential protein for cell growth, the absence of which results in an overall decline of edited mRNAs, while the levels of never-edited RNAs remain unaltered. Repression of TbRGG1 expression has no effect on the 20S editosome and MRP1/2 complex. TAP-tag purification of TbRGG1 coisolated a novel multiprotein complex, and its association was further verified by TAP-tag analyses of two other components of the complex. TbRGG1 interaction with this complex appears to be mediated by RNA. Our results suggest that the TbRGG1 protein functions in stabilizing edited RNAs or editing efficiency and that the associated novel complex may have a role in mitochondrial RNA metabolism. We provisionally name it putative mitochondrial RNA-binding complex 1 (put-MRB complex 1).

Unexplained complexity of the mitochondrial genome and transcriptome in kinetoplastid flagellates

Kinetoplastids are flagellated protozoans, whose members include the pathogens Trypanosoma brucei, T. cruzi and Leishmania species, that are considered among the earliest diverging eukaryotes with a mitochondrion. This organelle has become famous because of its many unusual properties, which are unique to the order Kinetoplastida, including an extensive kinetoplast DNA network and U-insertion/deletion type RNA editing of its mitochondrial transcripts. In the last decade, considerable progress has been made in elucidating the complex machinery of RNA editing. Moreover, our understanding of the structure and replication of kinetoplast DNA has also dramatically improved. Much less however, is known, about the developmental regulation of RNA editing, its integration with other RNA maturation processes, stability of mitochondrial mRNAs, or evolution of the editing process itself. Yet the profusion of genomic data recently made available by sequencing consortia, in combination with methods of reverse genetics, hold promise in understanding the complexity of this exciting organelle, knowledge of which may enable us to fight these often medically important protozoans.

Functional complementation of Trypanosoma brucei RNA in vitro editing with recombinant RNA ligase

The approximately 20S RNA ligase-containing complex (L-complex) in trypanosomatid mitochondria interacts by means of RNA linkers with at least two other multiprotein complexes to mediate the editing of mitochondrial cryptogene transcripts. The L-complex contains approximately 16 proteins, including the two RNA-editing ligases (RELs), REL1 and REL2. Leishmania tarentolae REL1 and REL2 and Trypanosoma brucei REL1 were expressed as enzymatically active tandem affinity purification-tagged proteins in a Baculovirus system. When these proteins were added to mitochondrial lysates from T. brucei procyclic cells that were depleted of the cognate endogenous ligase by RNA interference down-regulation of expression, the added proteins were integrated into the L-complex, and, in the case of REL1, there was a complementation of in vitro-precleaved U-insertion and U-deletion editing activities of the 20S L-complex. Integration of the recombinant proteins did not occur or occurred at a very low level with noncognate ligase-depleted L-complex or with wild-type L-complex. A C-terminal region of the T. brucei recombinant REL1 downstream of the catalytic domain was identified as being involved in integration into the L-complex. The ability to perform functional complementation in vitro provides a powerful tool for molecular dissection of the editing reaction.

Cis-acting elements stimulating kinetoplastid guide RNA-directed editing

The coding sequence of several mitochondrial mRNAs of the kinetoplastid protozoa is created through the insertion and deletion of specific uridylates. The editing reactions are required to be highly specific in order to ensure that functional open reading frames are created in edited mRNAs and that potentially deleterious modification of normally nonedited sequence does not occur. Selection-amplification and mutagenesis were previously used to identify the optimal sequence requirements for in vitro editing. There is, however, a minority of natural editing sites with suboptimal sequence. Several cis-acting elements, obtained from an in vitro selection, are described here that are able to compensate for a suboptimal editing site. An A + U sequence element within the 5'-untranslated region of cytochrome b mRNA from Leishmania tarentolae is also demonstrated to function as a cis-acting guide RNA and is postulated to compensate for a suboptimal editing site in vivo. Two proteins within an enriched editing extract are UV-cross-linked to two different in vitro selected editing substrates more efficiently than poorly edited RNAs. The results suggest that these proteins contribute to the specificity of the editing reaction.

Uridine insertion/deletion RNA editing in trypanosome mitochondria: a complex business

The basic mechanism of uridine insertion/deletion RNA editing in mitochondria of kinetoplastid protists has been established for some time but the molecular details remained largely unknown. Recently, there has been significant progress in defining the molecular components of the editing reaction. A number of factors have been isolated from trypanosome mitochondria, some of which have been definitely implicated in the uridine insertion/deletion RNA editing reaction and others of which have been circumstantially implicated. Several protein complexes have been isolated which exhibit some editing activities, and the macromolecular organization of these complexes is being analyzed. In addition, there have been several important technical advances in the in vitro analysis of editing. In this review we critically examine the various factors and complexes proposed to be involved in RNA editing.

A 100-kD complex of two RNA-binding proteins from mitochondria of Leishmania tarentolae catalyzes RNA annealing and interacts with several RNA editing components

A stable 100-kD complex from mitochondria of Leishmania tarentolae containing two RNA-binding proteins, Ltp26 and Ltp28, was identified by cross-linking to unpaired 4-thiouridine nucleotides in a partially duplex RNA substrate. The genes were cloned and expressed and the complex was reconstituted from recombinant proteins in the absence of RNA or additional factors. The Ltp26 and Ltp28 proteins are homologs of gBP27 and gBP29 from Crithidia fasciculata and gBP25 and gBP21 from Trypanosoma brucei, respectively. The purified Ltp26/Ltp28 complex, the individual recombinant proteins, and the reconstituted complex are each capable of catalyzing the annealing of complementary RNAs, as was previously shown for gBP21 from T. brucei. A high-molecular-weight RNP complex consisting of the Ltp26/Ltp28 complex and several 55-60-kD proteins together with guide RNA could be purified from mitochondrial extract of L. tarentolae transfected with Ltp28-TAP. This complex also interacted in a less stable manner with the RNA ligase-containing L-complex and with the 3' TUTase. The Ltp26/Ltp28 RNP complex is a candidate for catalyzing the annealing of guide RNA and pre-edited mRNA in the initial step of RNA editing.

Mechanism of the gBP21-mediated RNA/RNA annealing reaction: matchmaking and charge reduction

The guide RNA-binding protein gBP21 has been characterized as a mitochondrial RNA/RNA annealing factor. The protein co-immunoprecipitates with RNA editing ribonucleoprotein complexes, which suggests that gBP21 contributes its annealing activity to the RNA editing machinery. In support of this view, gBP21 was found to accelerate the hybridization of cognate guide (g)RNA/pre-edited mRNA pairs. Here we analyze the mechanism of the gBP21-mediated RNA annealing reaction. Three possible modes of action are considered: chaperone function, matchmaker function and product stabilization. We conclude that gBP21 works as a matchmaker by binding to gRNAs as one of the two RNA annealing reactants. Three lines of evidence substantiate this model. First, gBP21 and gRNAs form a thermodynamically and kinetically stable complex in a 1 + 1 stoichiometry. Secondly, gRNA-bound gBP21 stabilizes single-stranded RNA, which can be considered the transition state in the annealing reaction. Thirdly, gBP21 has a low affinity for double-stranded RNAs, suggesting the release of the annealed reaction product after the hybridization step. In the process, up to six ionic bonds are formed between gBP21 and a gRNA, which decreases the net negative charge of the RNA. As a consequence, the electrostatic repulsion between the two annealing reactants is reduced favoring the hybridization reaction.

Cloning and characterization of two guide RNA-binding proteins from mitochondria of Crithidia fasciculata: gBP27, a novel protein, and gBP29, the orthologue of Trypanosoma brucei gBP21

In kinetoplastid protozoa, mitochondrial (mt) mRNAs are post-transcriptionally edited by insertion and deletion of uridylate residues, the information being provided by guide (g)RNAs. Currently popular mechanisms for the editing process envisage a series of consecutive 'cut-and-paste' reactions, carried out by a complex RNP machinery. Here we report on the purification, cloning and functional analysis of two gRNA-binding proteins of 28.8 (gBP29) and 26.8 kDa (gBP27) from mitochondria of the insect trypanosome Crithidia fasciculata. gBP29 and gBP27 proved to be similar, Arg + Ala-rich proteins, with pI values of approximately 10.0. gBP27 has no homology to known proteins, but gBP29 is the C.fasciculata orthologue of gBP21 from Trypanosoma brucei, a gRNA-binding protein that associates with active RNA editing complexes. As measured in UV cross-linking assays, His-tagged recombinant gBP29 and gBP27 bind to radiolabelled poly(U) and synthetic gRNAs, while competition experiments suggest a role for the gRNA 3'-(U)-tail in binding to these proteins. Immunoprecipitates of mt extracts generated with antibodies against gBP29 also contained gBP27 and vice versa. The immunoprecipitates further harbored a large proportion of the cellular content of four different gRNAs and of edited and pre-edited NADH dehydrogenase subunit 7 mRNAs, but only small amounts of mt rRNAs. In addition, the bulk of gBP29 and gBP27 co-eluted with gRNAs from gel filtration columns in the high molecular weight range. Together, these results suggest that the proteins are part of a large macromolecular complex(es). We infer that gBP29 and gBP27 are components of the C.fasciculata editing machinery that may interact with gRNAs.

Annealing of RNA editing substrates facilitated by guide RNA-binding protein gBP21

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.

Functions and mechanisms of RNA editing

RNA editing can be broadly defined as any site-specific alteration in an RNA sequence that could have been copied from the template, excluding changes due to processes such as RNA splicing and polyadenylation. Changes in gene expression attributed to editing have been described in organisms from unicellular protozoa to man, and can affect the mRNAs, tRNAs, and rRNAs present in all cellular compartments. These sequence revisions, which include both the insertion and deletion of nucleotides, and the conversion of one base to another, involve a wide range of largely unrelated mechanisms. Recent advances in the development of in vitro editing and transgenic systems for these varied modifications have provided a better understanding of similarities and differences between the biochemical strategies, regulatory sequences, and cellular factors responsible for such RNA processing events.

Trypanosome RNA editing: simple guide RNA features enhance U deletion 100-fold

Trypanosome RNA editing is a massive processing of mRNA by U deletion and U insertion, directed by trans-acting guide RNAs (gRNAs). A U deletion cycle and a U insertion cycle have been reproduced in vitro using synthetic ATPase (A6) pre-mRNA and gRNA. Here we examine which gRNA features are important for this U deletion. We find that, foremost, this editing depends critically on the single-stranded character of a few gRNA and a few mRNA residues abutting the anchor duplex, a feature not previously appreciated. That plus any base-pairing sequence to tether the upstream mRNA are all the gRNA needs to direct unexpectedly efficient in vitro U deletion, using either the purified editing complex or whole extract. In fact, our optimized gRNA constructs support faithful U deletion up to 100 times more efficiently than the natural gRNA, and they can edit the majority of mRNA molecules. This is a marked improvement of in vitro U deletion, in which previous artificial gRNAs were no more active than natural gRNA and the editing efficiencies were at most a few percent. Furthermore, this editing is not stimulated by most other previously noted gRNA features, including its potential ligation bridge, 3' OH moiety, any U residues in the tether, the conserved structure of the central region, or proteins that normally bind these regions. Our data also have implications about evolutionary forces active in RNA editing.

Transcriptional and post-transcriptional in organello labelling of Trypanosoma brucei mitochondrial RNA

In organello labelling of Trypanosoma brucei mitochondrial (mt) RNA was characterised with respect to nucleotide requirements and drug sensitivity. Mitochondrial transcriptional activity is maximal in the presence of all ribonucleoside-triphosphate NTPs, and can be inhibited by UTP depletion. Mitochondrial transcription can also be partially inhibited by actinomycin D (actD) or ethidium bromide (EtBr). Post-transcriptional UTP incorporation is insensitive to actinomycin D or ethidium bromide. Proteins were identified that interact with transcriptional and post-transcriptionally labelled RNAs, and confirm the in vitro RNA-binding properties discovered for a number of T. brucei mt proteins. These experiments reveal new strategies for studying mt transcription and processing in T. brucei mitochondria.

UTP-dependent and -independent pathways of mRNA turnover in Trypanosoma brucei mitochondria

Although primary transcripts are polycistronic in the mitochondria of Trypanosoma brucei, steady-state levels of mature, monocistronic RNAs change throughout the parasitic life cycle. This indicates that steady-state RNA abundance is controlled by posttranscriptional mechanisms involving differential RNA stability. In this study, in organello pulse-chase labeling experiments were used to analyze the stability of different T. brucei mitochondrial RNA populations. In this system, total RNA and rRNA are stable for many hours. In contrast, mRNAs can be degraded by two biochemically distinct turnover pathways. The first pathway results in the rapid degradation of mRNA (half-life [t(1/2)] of 11 to 18 min) and is dependent upon the presence of an mRNA poly(A) tail. Remarkably, this pathway also requires the addition of UTP and therefore is termed UTP dependent. The second pathway results in slow turnover of mitochondrial mRNA (t(1/2) of approximately 3 h) and is not dependent upon the presence of an mRNA poly(A) tail or the addition of exogenous UTP. In summary, these results demonstrate the presence of a novel, UTP-dependent degradation pathway for T. brucei mitochondrial mRNAs and reveal an unprecedented role for both UTP and mRNA polyadenylation in T. brucei mitochondrial gene expression.

Localization of riboproteins in a trypanosomatid mitochondrion

There is growing evidence in support of mitochondrial translation in trypanosomes but mitoribosomes have never been characterized or localized in these parasites. On RNA-protein blots we identified several proteins from the trypanosomatid Crithidia fasciculata which bound the parasite's 12S and 9S mitochondrial ribosomal RNAs. Two of these proteins had significant amino acid sequence homology to riboproteins S8 and S21 across phyla. Immunoelectron microscopy revealed that antibodies raised against the two proteins react with matrix components in the C. fasciculata mitochondrion. Our data thus provide, we believe for the first time, evidence for the presence of riboproteins within a trypanosomatid mitochondrion, bound, possibly, to the 12S and 9S RNAs. The proteins were immunologically related to two cytosolic riboproteins which were also of identical size, suggesting the interesting possibility that the same set of riboproteins is shared between the cytosol and the mitochondrion in this parasite.

Uridine insertion/deletion RNA editing in trypanosome mitochondria--a review

The uridine insertion/deletion RNA editing in trypanosome mitochondria is a unique posttranscriptional RNA maturation process that involves the addition or removal of uridine residues at precise sites usually within the coding regions of mitochondrial transcripts. This process creates initiation and termination codons, corrects frameshifts and even builds entire open-reading frames from nonsense sequences. The development of several in-vitro editing assays has provided much insight into the molecular mechanism of RNA editing, which appears to involve cleavage, U addition, exonuclease trimming and ligation, essentially as proposed in the original 'enzyme cascade' model (Blum, B., Bakalara, N., Simpson, L., 1990. A model for RNA editing in kinetoplastid mitochondria: 'Guide' RNA molecules transcribed from maxicircle DNA provide the edited information. Cell 60, 189-198). However, little is known about the biochemical properties of the proteins involved and the significance and role of this process. This article is a review of recent findings on uridine-insertion/deletion editing in trypanosome mitochondria, with an emphasis on the proteins isolated and characterized that may have a role in this process.

The mitochondrial RNA ligase from Leishmania tarentolae can join RNA molecules bridged by a complementary RNA

A biochemical characterization was performed with a partially purified RNA ligase from isolated mitochondria of Leishmania tarentolae. This ligase has a K(m) of 25 +/- 0.75 nM and a V(max) of 1.0 x 10(-4) +/- 2.4 x 10(-4) nmol/min when ligating a nicked double-stranded RNA substrate. Ligation was negatively affected by a gap between the donor and acceptor nucleotides. The catalytic efficiency of the circularization of a single-stranded substrate was 5-fold less than that of the ligation of a nicked substrate. These properties of the mitochondrial RNA ligase are consistent with an expected in vivo role in the process of uridine insertion/deletion RNA editing, in which the mRNA cleavage fragments are bridged by a cognate guide RNA.

Knockout of the glutamate dehydrogenase gene in bloodstream Trypanosoma brucei in culture has no effect on editing of mitochondrial mRNAs

Glutamate dehydrogenase (GDH) was shown previously to bind the 3' oligo[U] tail of the mitochondrial guide RNAs (gRNAs) of Leishmania tarentolae, apparently in the dinucleotide pocket (Bringaud F, Stripecke R, Frech GC, Freedland S, Turck C, Byrne EM, Simpson L. Mol. Cell. Biol. 1997; 17:3915-3923). Bloodstream Trypanosoma brucei cells in culture represent a good system to investigate the genetic effects of knocking out kinetoplastid nuclear genes to test a role in RNA editing, since editing of several mitochondrial genes occurs but is dispensable for viability (Corell RA, Myler P, Stuart K. Mol. Biochem. Parasitol. 1994; 64:65-74 and Stuart K. In: Benne R, editor. RNA editing--the alteration of protein coding sequences of RNA. New York: Ellis Horwood, 1993:25-52). Both GDH alleles of bloodstream T. brucei in culture were replaced by drug resistant markers without any effect on viability. The ratios of edited to unedited mRNAs for several cryptogenes were assayed by primer extension analysis. The steady state abundances of these edited RNAs were unaffected by the double knockout. This evidence suggests that GDH may not play a role in the editing reaction in bloodstream trypanosomes in culture, but this conclusion is tentative since there could be redundant genes for any biological function. We employed a double allelic replacement technique to generate a tetracycline inducible conditional expression of an ectopic copy of the deleted gene in bloodstream trypanosomes in culture. We used this strategy for genes encoding mitochondrial proteins which are not required during this stage of the life cycle, but as a general strategy it should be appropriate for generation of conditional null mutants for essential genes as well.

Trypanosoma brucei RBP16 is a mitochondrial Y-box family protein with guide RNA binding activity

Trypanosoma brucei mitochondria possess a unique mechanism of mRNA maturation called RNA editing. In this process, uridylate residues are inserted and deleted posttranscriptionally into pre-mRNA to create translatable messages. The genetic information for RNA editing resides in small RNA molecules called guide RNAs (gRNAs). Thus, proteins in direct contact with gRNA are likely to catalyze or influence RNA editing. Herein we characterize an abundant gRNA-binding protein from T. brucei mitochondria. This protein, which we term RBP16 (for RNA-binding protein of 16 kDa), binds to different gRNA molecules. The major determinant of this interaction is the oligo(U) tail, present on the 3'-ends of gRNAs. RBP16 forms multiple, stable complexes with gRNA in vitro, and immunoprecipitation experiments provide evidence for an association between RBP16 and gRNA within T. brucei mitochondria. Mature RBP16 contains a cold shock domain at the N terminus and a C-terminal region rich in arginine and glycine. The presence of the cold shock domain places RBP16 as the first organellar member of the highly conserved Y-box protein family. The arginine and glycine rich C terminus in combination with the cold shock domain predicts that RBP16 will be involved in the regulation of gene expression at the posttranscriptional level.

Association of guide RNA binding protein gBP21 with active RNA editing complexes in Trypanosoma brucei

RNA editing in Trypanosoma brucei mitochondria produces mature mRNAs by a series of enzyme-catalyzed reactions that specifically insert or delete uridylates in association with a macromolecular complex. Using a mitochondrial fraction enriched for in vitro RNA editing activity, we produced several monoclonal antibodies that are specific for a 21-kDa guide RNA (gRNA) binding protein initially identified by UV cross-linking. Immunofluorescence studies localize the protein to the mitochondrion, with a preference for the kinetoplast. The antibodies cause a supershift of previously identified gRNA-specific ribonucleoprotein complexes and immunoprecipitate in vitro RNA editing activities that insert and delete uridylates. The immunoprecipitated material also contains gRNA-specific endoribonuclease, terminal uridylyltransferase, and RNA ligase activities as well as gRNA and both edited and unedited mRNA. The immunoprecipitate contains numerous proteins, of which the 21-kDa protein, a 90-kDa protein, and novel 55- and 16-kDa proteins can be UV cross-linked to gRNA. These studies indicate that the 21-kDa protein associates with the ribonucleoprotein complex (or complexes) that catalyze RNA editing.

Trypanosoma brucei TBRGG1, a mitochondrial oligo(U)-binding protein that co-localizes with an in vitro RNA editing activity

We report the characterization of a Trypanosoma brucei 75-kDa protein of the RGG (Arg-Gly-Gly) type, termed TBRGG1. Dicistronic and monocistronic transcripts of the TBRGG1 gene were produced by both alternative splicing and polyadenylation. TBRGG1 was found in two or three forms that differ in their electrophoretic mobility on SDS-polyacrylamide gel electrophoresis gels, one of which was more abundant in the procyclic form of the parasite. TBRGG1 was localized to the mitochondrion and appeared to be more abundant in bloodstream intermediate and stumpy forms in which the mitochondrion reactivates and during the procyclic stage, which possesses a fully functional mitochondrion. This protein was characterized to display oligo(U) binding characteristics and was found to co-localize with an in vitro RNA editing activity in a sedimentation analysis. TBRGG1 most likely corresponds to the 83-kDa oligo(U)-binding protein previously identified by UV cross-linking of guide RNA to mitochondrial lysates (Leegwater, P., Speijer, D., and Benne, R. (1995) Eur. J. Biochem. 227, 780-786).

Investigating the mechanism and machinery of RNA editing

RNA editing in trypanosomes produces mature mRNAs by posttranscriptional guide RNA (gRNA)-directed uridylate insertion and deletion. This article describes methods for the study of RNA editing with an emphasis on an in vitro editing system that was used to explore the general mechanism of editing and that can be adapted for more in-depth studies of this intriguing and important process. Methods used to investigate the macromolecular complex that catalyzes RNA editing are also described. This complex is composed of multiple proteins and contains several catalytic activities. It is in the early stages of characterization. The methods described here are intended to assist in its further analysis.

Purification of a functional enzymatic editing complex from Trypanosoma brucei mitochondria

Kinetoplastid mitochondrial RNA editing, the insertion and deletion of U residues, is catalyzed by sequential cleavage, U addition or removal, and ligation reactions and is directed by complementary guide RNAs. We have purified a approximately 20S enzymatic complex from Trypanosoma brucei mitochondria that catalyzes a complete editing reaction in vitro. This complex possesses all four activities predicted to catalyze RNA editing: gRNA-directed endonuclease, terminal uridylyl transferase, 3' U-specific exonuclease, and RNA ligase. However, it does not contain other putative editing complex components: gRNA-independent endonuclease, RNA helicase, endogenous gRNAs or pre-mRNAs, or a 25 kDa gRNA-binding protein. The complex is composed of eight major polypeptides, three of which represent RNA ligase. These findings identify polypeptides representing catalytic editing factors, reveal the nature of this approximately 20S editing complex, and suggest a new model of editosome assembly.

Mitochondrial glutamate dehydrogenase from Leishmania tarentolae is a guide RNA-binding protein

To identify specific proteins interacting with guide RNAs (gRNAs) in mitochondrial ribonucleoprotein complexes from Leishmania tarentolae, fractionated and unfractionated mitochondrial extracts were subjected to UV cross-linking with added labeled gRNA and also with [alpha-32P]UTP-labeled endogenous RNA. An abundant 110-kDa protein (p110) localized in the T-V complex, which sediments in glycerol gradients at the leading edge of the 10S terminal uridylyltransferase peak, was found to interact with both types of labeled RNAs. The p110 protein was gel isolated and subjected to microsequence analysis, and the gene was cloned. The sequence revealed significant similarity with mitochondrial glutamate dehydrogenases. A polyclonal antiserum was raised against a recombinant fragment of the p110 gene and was used to demonstrate a stable and specific gRNA-binding activity by coimmunoprecipitation and competitive gel shift analyses. Complex formation was strongly inhibited by competition with poly(U) or by deletion or substitution of the gRNA 3' oligo(U) tail. Also, addition of a 3' oligo(U) tail to an unrelated transcript was sufficient for p110 binding. Both the gRNA-binding activity of the p110 protein and in vitro gRNA-independent and gRNA-dependent uridine insertion activities in the mitochondrial extract were inhibited by high concentrations of dinucleotides.

A three-dimensional working model for a guide RNA from Trypanosoma brucei

RNA editing in protozoan parasites is a mitochondrial RNA processing reaction in which exclusively uridylate residues are inserted into, and less frequently deleted from, pre-mRNAs. Molecules central to the process are so-called guide RNAs (gRNAs) which function as templates in the reaction. For a detailed molecular understanding of the mechanism of the editing process knowledge of structural features of gRNAs will be essential. Here we report on a computer-assisted molecular modelling approach to construct the first three-dimensional gRNA model for gND7-506, a ND7-specific gRNA from Trypanosoma brucei. The modelling process relied on chemical modification and enzymatic probing data and was validated by in vitro mutagenesis experiments. The model predicts a reasonably compact structure, where two stem/loop secondary structure elements are brought into close proximity by a triple A tertiary interaction, forming a core element within the centre of the molecule. The model further suggests that the surface of the gRNA is primarily made up of the sugar-phoshate backbone. On the basis of the model, footprinting experiments of gND7-506 in a complex with the gRNA binding protein gBP21 could successfully be interpreted and provide a first picture for the assembly of gRNAs within a ribonucleoprotein complex.

RNA editing in kinetoplastid parasites: what to do with U

The editing of the mitochondrial RNAs of kinetoplastid protozoa is a bizarre form of transcript maturation that involves insertion and deletion of uridylate residues. Editing leads to the formation of translational initiation and termination codons, the correction of gene-encoded reading frame shifts and the creation of complete reading frames in mRNAs. It is therefore an essential step in mitochondrial gene expression.

RNA editing in kinetoplastid protozoa

Mitochondrial transcripts in kinetoplastids undergo remarkable posttranscriptional editing by uridylate insertion and deletion. The often dramatic remodeling of pre-mRNA sequences is directed by small guide RNAs (gRNAs) to produce mature mRNAs. In vitro analyses of editing have been used to determine the mechanism of editing and show that editing occurs by a series of enzyme-catalyzed steps. They also show that chimeric gRNA/mRNA molecules are not editing intermediates as proposed but are aberrant end products of editing. The complexes and molecules that catalyze editing are now being identified and characterized. The origin of editing, its developmental regulation which helps control the switching between terminal respiratory systems during the life cycle of trypanosomes, and other areas for future study are discussed.

Trypanosoma brucei gBP21. An arginine-rich mitochondrial protein that binds to guide RNA with high affinity

RNA editing in Trypanosoma brucei is a mitochondrial RNA processing reaction that results in the insertion and deletion of uridylate residues into otherwise untranslatable mRNAs. The process is directed by guide RNAs which function to specify the edited sequence. RNA editing in vitro requires mitochondrial protein extracts and guide RNAs have been identified as part of high molecular weight ribonucleoprotein complexes. Within the complexes, the RNAs are in close contact with several mitochondrial proteins and here we describe the isolation and cloning of a gRNA-interacting polypeptide from Trypanosoma brucei. The protein was named gBP21 for guide RNA-binding protein of 21 kDa. gBP21 shows no homology to proteins in other organisms, it is arginine-rich and binds to gRNA molecules with a dissociation constant in the nanomolar range. The protein does not discriminate for differences in the primary structures of gRNAs and thus likely binds to higher order structural features common to all gRNA molecules. gBP21 binding does not perturb the overall structure of gRNAs but the gRNA/gBP21 ribonucleoprotein complex is more stable than naked guide RNAs. Although the protein is arginine-rich, the free amino acid or an arginine-rich peptide were not able to inhibit the association to the RNAs. In contrast, the gRNA-gBP21 complex formation was sensitive to potassium and ammonium cations, thus indicating a contribution of ionic contacts to the binding.

RNA editing: how a message is changed

Considerable progress has been made in unraveling the mechanistic features of RNA editing processes in a number of genetic systems. Recent highlights include the identification of the catalytic subunit of the mammalian apolipoprotein B mRNA editing enzyme as a zinc-dependent cytidine deaminase that binds to RNA, the demonstration that adenosines in brain glutamate receptor pre-mRNAs are converted into inosines and that double-stranded RNA A deaminase (dsRAD), the candidate enzyme, is another zinc-dependent RNA nucleotide deaminase, and a mounting body of evidence for a cleavage-ligation mechanism for U insertion/deletion editing in kinetoplastid protozoa.

The secondary structure of guide RNA molecules from Trypanosoma brucei

RNA editing in kinetoplastid organisms is a mitochondrial RNA processing phenomenon that is characterized by the insertion and deletion of uridine nucleotides into incomplete mRNAs. Key molecules in the process are guide RNAs which direct the editing reaction by virtue of their primary sequences in an RNA-RNA interaction with the pre-edited mRNAs. To understand the molecular details of this reaction, especially potential RNA folding and unfolding processes as well as assembly phenomena with mitochondrial proteins, we analyzed the secondary structure of four different guide RNAs from Trypanosoma brucei at physiological conditions. By using structure-sensitive chemical and enzymatic probes in combination with spectroscopic techniques we found that the four molecules despite their different primary sequences, fold into similar structures consisting of two imperfect hairpin loops of low thermodynamic stability. The molecules melt in two-state monomolecular transitions with Tms between 33 and 39 degrees C and transition enthalpies of -32 to -38 kcal/mol. Both terminal ends of the RNAs are single-stranded with the 3' ends possibly adopting a single-stranded, helical conformation. Thus, it appears that the gRNA structures are fine tuned to minimize stability for an optimal annealing reaction to the pre-mRNAs while at the same time maximizing higher order structural features to permit the assembly with other mitochondrial components into the editing machinery.

A possible role for the guide RNA U-tail as a specificity determinant in formation of guide RNA-messenger RNA chimeras in mitochondrial extracts of Crithidia fasciculata

Chimeric g(uide) RNA:pre-mRNA molecules are potential intermediates of the RNA editing process in kinetoplastid mitochondria. We have studied the characteristics of chimeric molecules formed in mitochondrial extracts of the insect trypanosomatid Crithidia fasciculata which had been supplied with synthetic NADH dehydrogenase (ND) subunit-7 gRNA and pre-mRNA variants. The ability of a gRNA to participate in chimera formation in this system depends on the possibility of base pairing with the pre-mRNA via the anchor sequence, but not on the presence of a U-tail or a full-length informational part. Chimeras formed with a specific gRNA:pre-mRNA pair displayed a large variation in length, due to variably sized 3' end truncations of the gRNA moieties and variation in the sites in the pre-mRNA to which the gRNAs were attached. Surprisingly, the presence of a U-tail in the gRNA for a large part determined the specificity of the linkage. In 60% of the cases gRNAs possessing a U-tail of at least one residue were attached to an editing site, whereas 75% of the gRNAs without Us were attached to non-editing sites. Furthermore, the chimera forming activity was greatly stimulated by the addition of ATP but not by AMP-CPP, an ATP-analogue with a non-hydrolyzable alpha-beta phosphate bond. This suggests the involvement in the chimera formation of an RNA ligase.