Rapid shifts in mitochondrial tRNA import in a plant lineage with extensive mitochondrial tRNA gene loss

In most eukaryotes, transfer RNAs (tRNAs) are one of the very few classes of genes remaining in the mitochondrial genome, but some mitochondria have lost these vestiges of their prokaryotic ancestry. Sequencing of mitogenomes from the flowering plant genus Silene previously revealed a large range in tRNA gene content, suggesting rapid and ongoing gene loss/replacement. Here, we use this system to test longstanding hypotheses about how mitochondrial tRNA genes are replaced by importing nuclear-encoded tRNAs. We traced the evolutionary history of these gene loss events by sequencing mitochondrial genomes from key outgroups (Agrostemma githago and Silene [=Lychnis] chalcedonica). We then performed the first global sequencing of purified plant mitochondrial tRNA populations to characterize the expression of mitochondrial-encoded tRNAs and the identity of imported nuclear-encoded tRNAs. We also confirmed the utility of high-throughput sequencing methods for the detection of tRNA import by sequencing mitochondrial tRNA populations in a species (Solanum tuberosum) with known tRNA trafficking patterns. Mitochondrial tRNA sequencing in Silene revealed substantial shifts in the abundance of some nuclear-encoded tRNAs in conjunction with their recent history of mt-tRNA gene loss and surprising cases where tRNAs with anticodons still encoded in the mitochondrial genome also appeared to be imported. These data suggest that nuclear-encoded counterparts are likely replacing mitochondrial tRNAs even in systems with recent mitochondrial tRNA gene loss, and the redundant import of a nuclear-encoded tRNA may provide a mechanism for functional replacement between translation systems separated by billions of years of evolutionary divergence.

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Rapid Shifts in Mitochondrial tRNA Import in a Plant Lineage with Extensive Mitochondrial tRNA Gene Loss

Molecular Biology and Evolution ◽

10.1093/molbev/msab255 ◽

2021 ◽

Author(s):

Jessica M Warren ◽

Thalia Salinas-Giegé ◽

Deborah A Triant ◽

Douglas R Taylor ◽

Laurence Drouard ◽

...

Keyword(s):

Mitochondrial Genome ◽

Gene Loss ◽

Trna Gene ◽

Flowering Plant ◽

Trna Genes ◽

Evolutionary Divergence ◽

Mitochondrial Trna ◽

Trna Import ◽

History Of ◽

Mitochondrial Trna Gene

Abstract In most eukaryotes, transfer RNAs (tRNAs) are one of the very few classes of genes remaining in the mitochondrial genome, but some mitochondria have lost these vestiges of their prokaryotic ancestry. Sequencing of mitogenomes from the flowering plant genus Silene previously revealed a large range in tRNA gene content, suggesting rapid and ongoing gene loss/replacement. Here, we use this system to test longstanding hypotheses about how mitochondrial tRNA genes are replaced by importing nuclear-encoded tRNAs. We traced the evolutionary history of these gene loss events by sequencing mitochondrial genomes from key outgroups (Agrostemma githago and Silene [=Lychnis] chalcedonica). We then performed the first global sequencing of purified plant mitochondrial tRNA populations to characterize the expression of mitochondrial-encoded tRNAs and the identity of imported nuclear-encoded tRNAs. We also confirmed the utility of high-throughput sequencing methods for the detection of tRNA import by sequencing mitochondrial tRNA populations in a species (Solanum tuberosum) with known tRNA trafficking patterns. Mitochondrial tRNA sequencing in Silene revealed substantial shifts in the abundance of some nuclear-encoded tRNAs in conjunction with their recent history of mt-tRNA gene loss and surprising cases where tRNAs with anticodons still encoded in the mitochondrial genome also appeared to be imported. These data suggest that nuclear-encoded counterparts are likely replacing mitochondrial tRNAs even in systems with recent mitochondrial tRNA gene loss, and the redundant import of a nuclear-encoded tRNA may provide a mechanism for functional replacement between translation systems separated by billions of years of evolutionary divergence.

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Evidence for Import of a Lysyl-tRNA into Marsupial Mitochondria

Molecular Biology of the Cell ◽

10.1091/mbc.12.9.2688 ◽

2001 ◽

Vol 12 (9) ◽

pp. 2688-2698 ◽

Cited By ~ 53

Author(s):

Marion Dörner ◽

Markus Altmann ◽

Svante Pääbo ◽

Mario Mörl

Keyword(s):

Secondary Structure ◽

Rna Editing ◽

Trna Gene ◽

Nuclear Genome ◽

Mitochondrial Genomes ◽

Primary Sequence ◽

Mitochondrial Trna ◽

Trna Import ◽

Mitochondrial Trna Gene

The mitochondrial tRNA gene for lysine was analyzed in 11 different marsupial mammals. Whereas its location is conserved when compared with other vertebrate mitochondrial genomes, its primary sequence and inferred secondary structure are highly unusual and variable. For example, eight species lack the expected anticodon. Because the corresponding transcripts are not altered by any RNA-editing mechanism, the lysyl-tRNA gene seems to represent a mitochondrial pseudogene. Purification of marsupial mitochondria and in vitro aminoacylation of isolated tRNAs with lysine, followed by analysis of aminoacylated tRNAs, show that a nuclear-encoded tRNALys is associated with marsupial mitochondria. We conclude that a functional tRNALys encoded in the nuclear genome is imported into mitochondria in marsupials. Thus, tRNA import is not restricted to plant, yeast, and protozoan mitochondria but also occurs also in mammals.

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PHYLOGENETIC ANALYSES OF FRINGILLIDAE (AVES: PASSERIFORMES) USING MITOCHONDRIAL tRNA GENE SEQUENCES AND SECONDARY STRUCTURE

Journal of Biological System ◽

10.1142/s0218339006001908 ◽

2006 ◽

Vol 14 (03) ◽

pp. 413-424

Author(s):

BO CUI ◽

FEI MA ◽

XIANG WANG ◽

YI SUN ◽

LI YU ◽

...

Keyword(s):

Phylogenetic Trees ◽

Trna Gene ◽

Structural Characteristics ◽

Phylogenetic Analyses ◽

Likelihood Method ◽

Trna Genes ◽

Gene Sequences ◽

Mitochondrial Trna ◽

Mitochondrial Trna Genes ◽

Mitochondrial Trna Gene

Fringillidae is a large and diverse family of Passeriformes. So far, however, Fringillidae relationships deduced from morphological features and by a number of molecular approaches have remained unproven. Recently, much attention has been attracted to mitochondrial tRNA genes, whose sequence and secondary structural characteristics have shown to be useful for Acrodont Lizards and deep-branch phylogenetic studies. In order to identify useful phylogenetic markers and test Fringillidae relationships, we have sequenced three major clusters of mitochondrial tRNA genes from 15 Fringillidae taxa. A coincident tree, with coturnix as outgroup, was obtained through Maximum-likelihood method using combined dataset of 11 mitochondrial tRNA gene sequences. The result was similar to that through Neighbor-joining but different from Maximum-parsimony methods. Phylogenetic trees constructed with stem-region sequences of 11 genes had many different topologies and lower confidence than with total sequences. On the other hand, some secondary structural characteristics may provide phylogenetic information on relatively short internal branches at under-genus level. In summary, our data indicate that mitochondrial tRNA genes can achieve high confidence on Fringillidae phylogeny at subfamily level, and stem-region sequences may be suitable only at above-family level. Secondary structural characteristics may also be useful to resolve phylogenetic relationship between different genera of Fringillidae with good performance.

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Frequent tRNA gene translocation towards the boundaries with control regions contributes to the highly dynamic mitochondrial genome organization of the parasitic lice of mammals

BMC Genomics ◽

10.1186/s12864-021-07859-w ◽

2021 ◽

Vol 22 (1) ◽

Author(s):

Wen-Ge Dong ◽

Yalun Dong ◽

Xian-Guo Guo ◽

Renfu Shao

Keyword(s):

Mitochondrial Genome ◽

Control Region ◽

Genome Organization ◽

Trna Gene ◽

Trna Genes ◽

Single Chromosome ◽

Gene Translocation ◽

Sucking Lice ◽

Different Types ◽

Mt Genome

Abstract Background The typical single-chromosome mitochondrial (mt) genome of animals has fragmented into multiple minichromosomes in the lineage Mitodivisia, which contains most of the parasitic lice of eutherian mammals. These parasitic lice differ from each other even among congeneric species in mt karyotype, i.e. the number of minichromosomes, and the gene content and gene order in each minichromosome, which is in stark contrast to the extremely conserved single-chromosome mt genomes across most animal lineages. How fragmented mt genomes evolved is still poorly understood. We use Polyplax sucking lice as a model to investigate how tRNA gene translocation shapes the dynamic mt karyotypes. Results We sequenced the full mt genome of the Asian grey shrew louse, Polyplax reclinata. We then inferred the ancestral mt karyotype for Polyplax lice and compared it with the mt karyotypes of the three Polyplax species sequenced to date. We found that tRNA genes were entirely responsible for mt karyotype variation among these three species of Polyplax lice. Furthermore, tRNA gene translocation observed in Polyplax lice was only between different types of minichromosomes and towards the boundaries with the control region. A similar pattern of tRNA gene translocation can also been seen in other sucking lice with fragmented mt genomes. Conclusions We conclude that inter-minichromosomal tRNA gene translocation orientated towards the boundaries with the control region is a major contributing factor to the highly dynamic mitochondrial genome organization in the parasitic lice of mammals.

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Role of nuclear genes in expression of a mitochondrial tRNA gene in Saccharomyces cerevisiae

Molecular and Cellular Biology ◽

10.1128/mcb.3.3.371-379.1983 ◽

1983 ◽

Vol 3 (3) ◽

pp. 371-379

Author(s):

M Wesolowski ◽

C Palleschi ◽

L Frontali ◽

H Fukuhara

Keyword(s):

Saccharomyces Cerevisiae ◽

Trna Gene ◽

Mitochondrial Gene ◽

Nuclear Genes ◽

Yeast Mitochondria ◽

Mitochondrial Trna ◽

Genetic Crosses ◽

Mitochondrial Trna Gene

In yeast mitochondria, most of the isoaccepting species of tyrosyl tRNA are coded by a mitochondrial gene, tyrA. A particular isoaccepting species is coded by a second mitochondrial gene, tyrB. This gene is not expressed in certain strains of yeast which show no deficient phenotype. Genetic crosses between strains expressing or not expressing the tyrB gene demonstrate that expression is controlled by specific nuclear genes and that a mutation of the tyrA gene can be bypassed when the tyrB gene is operative.

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