scholarly journals Mitochondrial Dual-coding Genes in Trypanosoma brucei

2017 ◽  
Author(s):  
Laura E. Kirby ◽  
Donna Koslowsky
Keyword(s):  
Trypanosoma Brucei ◽  
Rna Editing ◽  
Genetic Drift ◽  
Mitochondrial Genes ◽  
Open Reading Frame ◽  
Dual Coding ◽  
Mutational Bias ◽  
Reading Frame ◽  
African Trypanosomes ◽  
Reading Frames

AbstractTrypanosoma brucei is transmitted between mammalian hosts by the tsetse fly. In the mammal, they are exclusively extracellular, continuously replicating within the bloodstream. During this stage, the mitochondrion lacks a functional electron transport chain (ETC). Successful transition to the fly, requires activation of the ETC and ATP synthesis via oxidative phosphorylation. This life cycle leads to a major problem: in the bloodstream, the mitochondrial genes are not under selection and are subject to genetic drift that endangers their integrity. Exacerbating this, T. brucei undergoes repeated population bottlenecks as they evade the host immune system that would create additional forces of genetic drift. These parasites possess several unique genetic features, including RNA editing of mitochondrial transcripts. RNA editing creates open reading frames by the guided insertion and deletion of U-residues within the mRNA. A major question in the field has been why this metabolically expensive system of RNA editing would evolve and persist. Here, we show that many of the edited mRNAs can alter the choice of start codon and the open reading frame by alternative editing of the 5’ end. Analyses of mutational bias indicate that six of the mitochondrial genes may be dual-coding and that RNA editing allows access to both reading frames. We hypothesize that dual-coding genes can protect genetic information by essentially hiding a non-selected gene within one that remains under selection. Thus, the complex RNA editing system found in the mitochondria of trypanosomes provides a unique molecular strategy to combat genetic drift in non-selective conditions.Author SummaryIn African trypanosomes, many of the mitochondrial mRNAs require extensive RNA editing before they can be translated. During this process, each edited transcript can undergo hundreds of cleavage/ligation events as U-residues are inserted or deleted to generate a translatable open reading frame. A major paradox has been why this incredibly metabolically expensive process would evolve and persist. In this work, we show that many of the mitochondrial genes in trypanosomes are dual-coding, utilizing different reading frames to potentially produce two very different proteins. Access to both reading frames is made possible by alternative editing of the 5’ end of the transcript. We hypothesize that dual-coding genes may work to protect the mitochondrial genes from mutations during growth in the mammalian host, when many of the mitochondrial genes are not being used. Thus, the complex RNA editing system may be maintained because it provides a unique molecular strategy to combat genetic drift.

scholarly journals Cell-line specific RNA editing patterns in Trypanosoma brucei suggest a unique mechanism to generate protein variation in a system intolerant to genetic mutations

2019 ◽  
Vol 48 (3) ◽  
pp. 1479-1493
Author(s):  
Laura E Kirby ◽  
Donna Koslowsky
Keyword(s):  
Trypanosoma Brucei ◽  
Rna Editing ◽  
Dual Coding ◽  
Reading Frame ◽  
Guide Rnas ◽  
Insertion And Deletion ◽  
Editing Domain ◽  
Ribosomal Protein S12 ◽  
Reading Frames ◽  
Unique Mechanism

Abstract Trypanosoma brucei possesses a highly complex RNA editing system that uses guide RNAs to direct the insertion and deletion of uridines in mitochondrial mRNAs. These changes extensively alter the target mRNAs and can more than double them in length. Recently, analyses showed that several of the edited genes possess the capacity to encode two different protein products. The overlapped reading frames can be accessed through alternative RNA editing that shifts the translated reading frame. In this study, we analyzed the editing patterns of three putative dual-coding genes, ribosomal protein S12 (RPS12), the 5′ editing domain of NADH dehydrogenase subunit 7 (ND7 5′), and C-rich region 3 (CR3). We found evidence that alternatively 5′-edited ND7 5′ and CR3 transcripts are present in the transcriptome, providing evidence for the use of dual ORFs in these transcripts. Moreover, we found that CR3 has a complex set of editing pathways that vary substantially between cell lines. These findings suggest that alternative editing can work to introduce genetic variation in a system that selects against nucleotide mutations.

scholarly journals Mitochondrial DNAs provide insight into trypanosome phylogeny and molecular evolution

2020 ◽  
Author(s):  
Christopher Kay ◽  
Tom A Williams ◽  
Wendy Gibson
Keyword(s):  
Molecular Evolution ◽  
Trypanosoma Brucei ◽  
Rna Editing ◽  
Phylogenetic Trees ◽  
Nucleotide Composition ◽  
Sub Saharan Africa ◽  
African Trypanosomes ◽  
Animal Pathogens ◽  
Recent Emergence ◽  
The Impact

Abstract Background: Trypanosomes are single-celled eukaryotic parasites characterised by the unique biology of their mitochondrial DNA (mtDNA). African livestock trypanosomes impose a major burden on agriculture across sub-Saharan Africa, but are poorly understood compared to those that cause sleeping sickness and Chagas disease in humans. Here we explore the potential of trypanosome mtDNA to study the evolutionary history of trypanosomes and the molecular evolution of their mtDNAs.Results: We used long-read sequencing to completely assemble mtDNAs from four previously uncharacterized African trypanosomes, and leveraged these assemblies to scaffold and assemble a further 103 trypanosome mtDNAs from published short-read data. While synteny was largely conserved, there were repeated, independent losses of Complex I genes. Comparison of edited and non-edited genes revealed the impact of RNA editing on nucleotide composition, with non-edited genes approaching the limits of GC loss. African tsetse-transmitted trypanosomes showed high levels of RNA editing compared to other trypanosomes. Whole mtDNA coding regions were used to construct time-resolved phylogenetic trees, revealing deep divergence events among isolates of the pathogens Trypanosoma brucei and T. congolense .Conclusions: Our mtDNA data represents a new resource for experimental and evolutionary analyses of trypanosome phylogeny, molecular evolution and function. Molecular clock analyses yielded a timescale for trypanosome evolution congruent with major biogeographical events in Africa and revealed the recent emergence of Trypanosoma brucei gambiense and T. equiperdum , major human and animal pathogens.

SOME HINTS ON OPEN READING FRAME STATISTICS — HOW ORF LENGTH DEPENDS ON SELECTION

1999 ◽  
Vol 10 (04) ◽  
pp. 635-643 ◽  
Author(s):  
AGNIESZKA GIERLIK ◽  
PAWEŁ MACKIEWICZ ◽  
MARIA KOWALCZUK ◽  
STANISŁAW CEBRAT ◽  
MIROSŁAW R. DUDEK
Keyword(s):  
Genetic Code ◽  
Dna Sequences ◽  
Nucleotide Composition ◽  
Open Reading Frames ◽  
Open Reading Frame ◽  
Antisense Strand ◽  
Coding Sequences ◽  
Reading Frame ◽  
Intergenic Sequences ◽  
Reading Frames

Coding sequences of DNA generate Open Reading Frames (ORFs) inside them with much higher frequency than random DNA sequences do, especially in the antisense strand. This is a specific feature of the genetic code. Since coding sequences are selected for their length, the generated ORFs are indirect results of this selection and their length is also influenced by selection. That is why ORFs found in any genome, even much longer ones than those spontaneously generated in random DNA sequences, should be considered as two different sets of ORFs: The first one coding for proteins, the second one generated by the coding ORFs. Even intergenic sequences possess greater capacity for generating ORFs than random DNA sequences of the same nucleotide composition, which seems to be a premise that intergenic sequences were generated from coding sequences by recombinational mechanisms.

scholarly journals Translation Termination Reinitiation between Open Reading Frame 1 (ORF1) and ORF2 Enables Capsid Expression in a Bovine Norovirus without the Need for Production of Viral Subgenomic RNA

2008 ◽  
Vol 82 (17) ◽  
pp. 8917-8921 ◽  
Author(s):  
Christopher J. McCormick ◽  
Omar Salim ◽  
Paul R. Lambden ◽  
Ian N. Clarke
Keyword(s):  
Hepg2 Cells ◽  
Nonstructural Protein ◽  
Translation Termination ◽  
Surrogate Marker ◽  
Open Reading Frames ◽  
Open Reading Frame ◽  
Subgenomic Rna ◽  
Reading Frame ◽  
Reading Frames ◽  
Open Reading Frame 1

ABSTRACT A generally accepted view of norovirus replication is that capsid expression requires production of a subgenomic transcript, the presence of capsid often being used as a surrogate marker to indicate the occurrence of viral replication. Using a polymerase II-based baculovirus delivery system, we observed capsid expression following introduction of a full-length genogroup 3 norovirus genome into HepG2 cells. However, capsid expression occurred as a result of a novel translation termination/reinitiation event between the nonstructural-protein and capsid open reading frames, a feature that may be unique to genogroup 3 noroviruses.

Modification of Trypanosoma brucei mitochondrial rRNA by posttranscriptional 3' polyuridine tail formation

1991 ◽  
Vol 11 (12) ◽  
pp. 5878-5884
Author(s):  
B K Adler ◽  
M E Harris ◽  
K I Bertrand ◽  
S L Hajduk
Keyword(s):  
Trypanosoma Brucei ◽  
Rna Editing ◽  
Total Cell ◽  
Metabolic Labeling ◽  
Mechanism Of Formation ◽  
Guide Rnas ◽  
Mitochondrial Rrna ◽  
Mitochondrial Transcripts ◽  
Reading Frames

Trypanosoma brucei mitochondrial transcripts can be posttranscriptionally processed by uridine addition or deletion. With editing of mRNAs, uridine addition and deletion create precisely altered reading frames. The addition of nonencoded uridines to mitochondrial guide RNAs results in a less precise modification. Although uridines are specifically added to the 3' termini, their number varies, which results in heterogeneous oligo(U) tails on guide RNAs. In this paper, we show that the mitochondrial 9S and 12S rRNAs are also modified by uridine addition. These modifications appear to have aspects in common with both RNA editing and oligo(U) tail formation. Metabolic labeling studies with intact mitochondria and [alpha-32P]UTP, in the absence of transcription, demonstrated the posttranscriptional timing of the event. T1 RNase comparison analyses of cytidine 3',5'-[5'-32P]biphosphate 3'-end-labeled and [alpha-32P]UTP metabolically labeled rRNAs, along with direct RNA sequencing of the 3' termini, identified the site of uridine addition and revealed the creation of an oligo(U) tail for both rRNAs. 12S and 9S rRNAs hybrid selected from total cell RNA exhibited the same modification, demonstrating the presence of this processing in vivo. Moreover, only 3'-poly(U)-tailed 9S and 12S rRNAs were detected in total cellular and mitochondrial RNAs, which suggests that they are the most abundant and probable mature forms. The 12S and 9S rRNA oligo(U) tails differed significantly from each other, with the 12S having a heterogeneous tail of 2 to 17 uridines and the 9S having a tail of precisely 11 uridines. The mechanism of formation and the function of the rRNA poly(U) tails remain to be determined.

scholarly journals Saccharomyces cerevisiae positive regulatory gene PET111 encodes a mitochondrial protein that is translated from an mRNA with a long 5' leader.

1987 ◽  
Vol 7 (8) ◽  
pp. 2728-2734 ◽  
Author(s):  
C A Strick ◽  
T D Fox
Keyword(s):  
Amino Acids ◽  
Regulatory Gene ◽  
Mitochondrial Protein ◽  
Nuclear Gene ◽  
Open Reading Frames ◽  
Open Reading Frame ◽  
Reading Frame ◽  
Amino Terminal ◽  
Interesting Pattern ◽  
Reading Frames

The yeast nuclear gene PET111 is required specifically for translation of the mitochondrion-coded mRNA for cytochrome c oxidase subunit II. We have determined the nucleotide sequence of a 3-kilobase segment of DNA that carries PET111. The sequence contains a single long open reading frame that predicts a basic protein of 718 amino acids. The PET111 gene product is a mitochondrial protein, since a hybrid protein which includes the amino-terminal 154 amino acids of PET111 fused to beta-galactosidase is specifically associated with mitochondria. PET111 is translated from a 2.9-kilobase mRNA which, interestingly, has an extended 5'-leader sequence containing four short open reading frames upstream of the long open reading frame. These open reading frames exhibit an interesting pattern of overlap with each other and with the PET111 reading frame.

Saccharomyces cerevisiae positive regulatory gene PET111 encodes a mitochondrial protein that is translated from an mRNA with a long 5' leader

1987 ◽  
Vol 7 (8) ◽  
pp. 2728-2734
Author(s):  
C A Strick ◽  
T D Fox
Keyword(s):  
Amino Acids ◽  
Regulatory Gene ◽  
Mitochondrial Protein ◽  
Nuclear Gene ◽  
Open Reading Frames ◽  
Open Reading Frame ◽  
Reading Frame ◽  
Amino Terminal ◽  
Interesting Pattern ◽  
Reading Frames

The yeast nuclear gene PET111 is required specifically for translation of the mitochondrion-coded mRNA for cytochrome c oxidase subunit II. We have determined the nucleotide sequence of a 3-kilobase segment of DNA that carries PET111. The sequence contains a single long open reading frame that predicts a basic protein of 718 amino acids. The PET111 gene product is a mitochondrial protein, since a hybrid protein which includes the amino-terminal 154 amino acids of PET111 fused to beta-galactosidase is specifically associated with mitochondria. PET111 is translated from a 2.9-kilobase mRNA which, interestingly, has an extended 5'-leader sequence containing four short open reading frames upstream of the long open reading frame. These open reading frames exhibit an interesting pattern of overlap with each other and with the PET111 reading frame.

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