Mitochondrial minicircles in the free-living bodonid Bodo saltans contain two gRNA gene cassettes and are not found in large networks.

In trypanosomatids, the majority of the guide (g) RNAs that provide the information for U-insertion/deletion RNA editing are encoded by minicircles that are catenated into large networks. In contrast, in the distantly related cryptobiid Trypanoplasma borreli, gRNA genes appear to reside in large 180-kb noncatenated DNA circles. To shed light on the evolutionary history and function of the minicircle network, we have analyzed minicircle organization in the free-living bodonid Bodo saltans, which is more closely related to trypanosomatids than T. borreli. We identified 1.4-kb circular DNAs as the B. saltans equivalent of minicircles via sequence analysis of 4 complete minicircles, 14 minicircle fragments, and 14 gRNAs. We show that each minicircle harbors two gRNA gene cassettes of opposite polarity residing in variable regions of about 200 nt in otherwise highly conserved molecules. In the conserved region, B. saltans minicircles contain a putative bent helix sequence and a degenerate dodecamer motif (CSB-3). Electron microscopy, sedimentation, and gel electrophoresis analyses showed no evidence for the existence of large minicircle networks in B. saltans, the large majority of the minicircles being present as circular and linear monomers (85-90%) with small amounts of catenated dimers and trimers. Our results provide the first example of a kinetoplastid species with noncatenated, gRNA gene-containing minicircles, which implies that the creation of minicircles and minicircle networks are separate evolutionary events.

Recording eye movements in mice: a new approach to investigate the molecular basis of cerebellar control of motor learning and motor timing.

The vestibulocerebellum is involved in the control of compensatory eye movements. To investigate its role in learning and timing of motor behavior, we investigated compensatory eye movements in mice with the use of search coils. Wild-type mice showed the ability to increase the gain of their vestibulo-ocular reflex by visuovestibular training. This adaptation did not occur in lurcher mice, a natural mouse mutant that completely lacks Purkinje cells. During the optokinetic reflex the phase of the eye movements of lurcher mice in reference to the stimulus lagged behind that of wild-type littermates, whereas during the vestibulo-ocular reflex it led that of the wild-type mice. During combined optokinetic and vestibular stimulation, the phase of the lurcher mice lagged behind that of the wild-type mice at the low stimulus frequencies, whereas it led the phase of the wild-type mice at the high frequencies. In addition, the optokinetic response of the lurcher mice showed a significantly longer latency during constant-velocity step stimulation than that of the wild-type mice. We conclude that Purkinje cells are necessary for both learning and timing of compensatory eye movements in mice. The present description of gain adaptation and phase dynamics provides the basis for studies in which the molecular mechanisms of cerebellar control of compensatory eye movements are investigated with the use of genetically manipulated mice.

Novel pattern of editing regions in mitochondrial transcripts of the cryptobiid Trypanoplasma borreli.

In mitochondria of Kinetoplastida belonging to the suborder Trypanosomatina, the nucleotide sequence of transcripts is post-transcriptionally edited via insertion and deletion of uridylate residues. In order to shed more light on the evolutionary history of this process we have searched for editing in mitochondrial RNAs of Trypanoplasma borreli, an organism belonging to the suborder Bodonina. We have cloned and sequenced a 5.3 kb fragment derived from a 37 kb mitochondrial DNA molecule which does not appear to be a part of a network structure and have found genes encoding cytochrome c oxidase (cox) subunit 1, cox 2 and apocytochrome (cyt) b, and genes encoding the small and large subunit mitoribosomal RNAs. The order in which these genes occur is completely different from that of trypanosomatid maxicircle genes. The 5' and 3' termini of both the cytb and cox1 gene are cryptic, the protein coding sequences being created by extensive insertion/deletion of Us in the corresponding mRNA sections. Phylogenetic analyses of the protein and ribosomal RNA sequences demonstrated that the separation between T.borreli and Trypanosomatina was an early event, implying that U-insertion/deletion processes are ancient. Different patterns of editing have persisted in different lineages, however, since editing of cox1 RNA and of relatively small 3'-terminal RNA sections is not found in trypanosomatids. In contrast, cox2 RNA which is edited in trypanosomatids by the insertion of four Us, is unedited in T.borreli.

RNA editing in mitochondria of cultured trypanosomatids: translatable mRNAs for NADH-dehydrogenase subunits are missing.

RNA editing in mitochondria of kinetoplastid protozoa involves the posttranscriptional insertion and deletion of uridylate residues in protein encoding regions of pre-mRNAs. Editing is required to remove gene-encoded translational defects or to convert a nonsense sequence into a sense message. In cultured trypanosomatids, however, translationally defective pre-mRNAs for a number of NADH-dehydrogenase subunits are not converted into functional mRNAs by editing. In this report, the available data are discussed in the context of current models for RNA editing.

Implications of novel guide RNA features for the mechanism of RNA editing in Crithidia fasciculata.

We have determined the relative steady state concentration of the two Crithidia fasciculata guide (g)RNAs involved in editing the two domains of mRNAs for NADH dehydrogenase (ND) subunit 7. We found that, although there was an 8-fold difference between the molar ratio of these two gRNAs relative to the (pre)-mRNA, the two domains are edited with a very similar frequency (around 50%). Also, for the editing of a given domain, many gRNA species exist with the same 5' end but with a different 3' uridylation site. Approximately 20% of these short gRNAs do not contain the information required for editing a complete domain, which may explain the high incidence of partially edited RNAs. Remarkably, genomically encoded Us are missing from two sites of a few of the gRNAs involved in editing apocytochrome b RNA. We speculate that these species are created by editing-like events. Both the short and complete forms of the ND7 gRNAs are found in chimeric molecules, in which the gRNA is covalently linked via its 3'-terminus to an editing site of pre-edited ND7 RNA. Some features of the chimeric molecules are at odds with current models of RNA editing: (i) U residues are completely absent from the connecting sequence of a number of these molecules, (ii) the ND7 gRNAs are frequently hooked up to the wrong editing domain of ND7 RNA, although other gRNAs are not found at these positions and (iii) in some chimeric molecules the gRNA appears to be linked to the 5' end of pre-edited RNA.

Conserved genes encode guide RNAs in mitochondria of Crithidia fasciculata.

RNA editing is the post-transcriptional alteration of the nucleotide sequence of RNA, which in trypanosome mitochondria is characterized by the insertion and deletion of uridine residues. It has recently been proposed that the information for the sequence alteration in Leishmania tarentolae is provided by small guide (g) RNAs encoded in the mitochondrial DNA [Blum et al. (1990) Cell, 60, 189-198]. We are studying the mechanism of RNA editing in the insect trypanosome Crithidia fasciculata and report that: (i) a full length, conventional DNA gene or an independently replicating RNA gene that could encode the edited MURF3 transcript is absent when probed for in sensitive, calibrated assay systems; (ii) in all cases (seven) investigated in C. fasciculata so far, putative gRNA genes are found in a position in the mitochondrial DNA virtually identical to that in L. tarentolae and (iii) also in C. fasciculata, the putative gRNA genes are transcribed into small RNAs with discrete 5' ends. These results provide strong evolutionary evidence in support of the participation of gRNAs in RNA editing. Remarkably, in C. fasciculata the basepaired region of some putative gRNA:mRNA hybrids contains a C:A non-Watson-Crick basepair.

RNA editing in transcripts of the mitochondrial genes of the insect trypanosome Crithidia fasciculata.

With the aid of cDNA and RNA sequence analysis, we have determined to what extent transcripts of mitochondrial maxicircle genes of the insect trypanosome Crithidia fasciculata are altered by RNA editing, a novel mechanism of gene expression which operates via the insertion and deletion of uridine residues. Editing of cytochrome c oxidase (cox) subunit II and III transcripts and of maxicircle unidentified reading frame (MURF) 2 RNA is limited to a small section and results in the creation of a potential AUG translational initiation codon (coxIII, MURF2) or the removal of a frameshift (coxII). No differences with the genomic sequences were observed in the remainder of these RNAs. Surprisingly, NADH dehydrogenase subunit I transcripts were completely unedited in the coding region, implying that an AUG translational initiation codon is absent. The partial ribosomal RNA sequences determined also conform to the gene sequences. Together these results lead to the conclusion that the unusual sequences predicted by the protein and rRNA genes must indeed be present in the gene products. Editing also occurred in the poly(A) tail of RNAs from all protein genes, including those that are unedited in the coding region. The tails display a large variation in AU sequence motifs. Finally, some cDNAs contained sequences absent from both the DNA and the edited RNA. Some of these may represent intermediates in the RNA editing process. We argue, however, that long runs of T may be artefacts of cDNA synthesis.

Transcripts from the frameshifted MURF3 gene from Crithidia fasciculata are edited by U insertion at multiple sites.

In trypanosome mitochondria an RNA editing process is operative, which co- or post-transcriptionally alters the nucleotide sequence of transcripts by insertion and/or deletion of U residues at specific sites. To increase our understanding of the mechanism of this process we have compared the nucleotide sequence of the frameshifted mitochondrial MURF3 gene from Crithidia fasciculata to that of a large number of MURF3 cDNAs. We found cDNAs derived from transcripts edited at two different sites in the protein coding sequence: (i) at the frameshift position five extra U residues connect the two reading frames and (ii) at the 5' terminus 22 inserted Us shift a putative initiator codon out of phase. The collection also contained cDNAs that were derived from non-edited transcripts. Partially edited sequences were not found, except in one cDNA, which contained an edited frameshift site in combination with a non-edited 5' terminus. The analysis further showed that MURF3 transcripts have a 3'-terminal poly(AU) extension, which varies in sequence. The implications of these results are discussed.

The nucleotide sequence of a 3.2 kb segment of mitochondrial maxicircle DNA from Crithidia fasciculata containing the gene for cytochrome oxidase subunit III, the N-terminal part of the apocytochrome b gene and a possible frameshift gene; further evidence for the use of unusual initiator triplets in trypanosome mitochondria.

A 3.2 kb segment of the maxicircle of Crithidia fasciculata mitochondrial (mt) DNA contains the gene for cytochrome oxidase subunit III (coxIII), the N-terminal portion of the gene for apocytochrome b (cytb) and two partially overlapping Unassigned Reading Frames (C.URF2/1). Transcript analysis of the segment reveals that both the coxIII gene and the C.URF2/1 area are transcribed into a pair of RNA products. With the C. fasciculata gene version as a probe, a coxIII gene could not be detected in nuclear and mtDNA of Trypanosoma brucei, indicating that the cytochrome oxidases of these two closely related trypanosome species may differ. The nucleotide homology in the N-terminal region of the coxIII and cytb genes in T. brucei, Leishmania tarentolae and C. fasciculata starts at a UUA leucine codon, which adds further support to the hypothesis that apart from AUG, other initiator triplets are used in trypanosomal mitochondria: UUG, CUG and UUA, all triplets coding for leucine in the universal code. Finally, the possibility is discussed that the two overlapping URFs (C.URF2/1) in fact represent a single, frameshift containing, gene.

Major transcript of the frameshifted coxII gene from trypanosome mitochondria contains four nucleotides that are not encoded in the DNA.

The mitochondrial cytochrome oxidase (cox) subunit II gene from trypanosomes contains a frameshift at amino acid 170. This gene is highly conserved in different trypanosome species, suggesting that it is functional. Sequence determination of coxII transcripts of T. brucei and C. fasciculata reveals four extra, reading frame-restoring nucleotides at the frameshift position that are not encoded in the DNA. Southern blot analysis of DNA of both trypanosome species failed to show the existence of a second version of the coxII gene. We conclude, therefore, that the extra nucleotides are added during or after transcription of the frameshift gene by an RNA-editing process.

Further characterization of the extremely small mitochondrial ribosomal RNAs from trypanosomes: a detailed comparison of the 9S and 12S RNAs from Crithidia fasciculata and Trypanosoma brucei with rRNAs from other organisms.

We have determined the nucleotide sequence of a maxi-circle segment from the insect trypanosome Crithidia fasciculata mitochondrial DNA, on which the genes for the major maxicircle transcripts of 9S and 12S are localized. The 5'-terminal sequences of these RNAs were determined by wandering spot analysis. The map coordinates of the 9S and 12S RNAs from Trypanosoma brucei were adjusted with respect to a previous report with the aid of primer extension analysis with reverse transcriptase. This approach allowed us to align the corresponding genes from both organisms which show an overall sequence homology of 77%. The 9S and 12S RNA genes from the two trypanosome species contain sequences, closely related to some of the regions that are universally conserved among ribosomal RNAs from members of the three primary kingdoms and their organelles, even though the overall level of sequence homology is extremely low. These universal sequences occur at positions in the 9S and 12S RNAs that are analogous to those occupied by their counterparts in authentic ribosomal RNAs. The characteristic secondary structure elements flanking these universal sequences in genuine ribosomal RNAs can also be formed in the trypanosomal 9S and 12S RNAs. These results provide unequivocal evidence for a ribosomal function of the 9S and 12S RNAs of trypanosomal mitochondria, notwithstanding their extremely small size (estimated to be 612 and 1141 nucleotides in C. fasciculata, 611 and 1150 nucleotides in T. brucei) and their unusual base composition (83% A+U).

The nucleotide sequence of a segment of Trypanosoma brucei mitochondrial maxi-circle DNA that contains the gene for apocytochrome b and some unusual unassigned reading frames.

The nucleotide sequence of a 2.5-kb segment of the maxi-circle of Trypanosoma brucei mtDNA has been determined. The segment contains the gene for apocytochrome b, which displays about 25% homology at the amino acid level to the apocytochrome b gene from fungal and mammalian mtDNAs. Northern blot and S1 nuclease analyses have yielded accurate map positions of an RNA species in an area that coincides with the reading frame. The segment also contains two pairs of overlapping unassigned reading frames, which lack homology with any known mitochondrial gene or URF. The DNA sequence in these areas is AG-rich (70%), resulting in URFs with an unusually high level of glycine and charged amino acids (60%). They may not encode proteins, in spite of their size and the fact that abundant transcripts are mapped in these areas.

Rapid evolution of genes coding for variant surface glycoproteins in trypanosomes.

We have used cloned DNA complementary to the messenger RNAs (mRNAs) for different variant surface glycoproteins (VSGs) of Trypanosoma brucei, stock 427, to study the degree of conservation of the corresponding nuclear genes in related trypanosome stocks. Conservation of restriction endonuclease cleavage sites in and around these genes were assessed by hybridization of the complementary DNA (cDNA) probes to nuclear DNA blots of these stocks. One of the genes (117) was found essentially unaltered in 11 out of 12 stocks. A second gene (118) was absent in five stocks. In the seven stocks that contained it, four forms of this 118 gene could be distinguished that differ by loss/gain of several restriction sites. A third gene (221) was only present in T. brucei 427 and in none of 11 other stocks. We conclude that a sub-set of the genes for the variant antigens evolves at a very high rate and we favour the hypothesis that this is due to local hypermutagenesis.

The isolation of plasmids containing DNA complementary to messenger RNA for variant surface glycoproteins of Trypanosoma brucei.

We have isolated poly(A)+ RNA from four antigenic variants (117, 118, 121, 221) of one clone of Trypanosoma brucei. Translation of these poly(A)+ RNAs in a rabbit reticulocyte lysate gave rise to proteins that could be precipitated with antisera against homologous variant surface glycoprotein, the protein responsible for antigenic variation in trypanosomes. From the electrophoretic mobility of these in vitro products in sodium dodecyl sulphate (SDS) gels we infer that variant surface glycoproteins (VSGs) are made as pre-proteins, which require trimming to yield mature VSGs. The total translation products from the four poly(A)+ RNAs produced a complex set of bands on SDS gels, which only differed in the region where the variant pre-glycoproteins migrated. The only detectable variation in the messenger RNA populations of these variants is, therefore, in the messenger RNA for variant pre-glycoproteins. We have made duplex DNA copies of these poly(A)+ RNAs, linked the complementary DNA to plasmid pBR322 by GC tailing and cloned this recombinant DNA in Escherichia coli. Colony hybridization with complementary DNA made on poly(A)+ RNA showed that 7--10% of the colonies contained DNA that hybridized only with the homologous probe. Plasmid DNA was isolated from ten such colonies (two or three of each variant complementary DNA), bound to diazobenzyloxymethyl-cellulose (DBM) paper and used to select complementary messenger RNA from total poly(A)+ RNA by hybridization. In eight cases the RNA recovered from the filter gave variant pre-glycoprotein as the predominant product of in vitro translation. Poly(A)+ RNA from each of the variants only hydridized to the homologous complementary DNA in filter hybridizations. Each trypanosome variant, therefore, contains no detectable messenger RNAs for the three heterologous variant-specific glycoproteins tested. We conclude from this lack of cross-hybridization that antigenic diversity in trypanosomes, unlike antibody diversity in mammals, does not involve the linkage of a repertoire of genes for the variable N-terminal half to a single gene for the C-terminal half of the VSGs.