人线粒体tRNA修饰碱基与遗传性脑肌病

人的多种遗传疾病与线粒体tRNA基因突变有关,这些突变导致疾病发生的分子机理是当前研究的热点.通过研究线粒体tRNA分子上的碱基修饰情况,人们发现了一类特殊的带有牛磺酸衍生物基团的修饰,这类修饰主要位于线粒体tRNALys和线粒体tRNALeu(UUR)反密码子第一位摆动(wobble)位点的碱基上.最近的研究表明,位于这两种线粒体tRNA基因上的多种突变与遗传性脑肌病相关,包括A8344G,A3243G,T3271C等等,它们可以导致tRNA上相应摆动位点的碱基修饰缺失.无论是在体外培养的带有相应突变的细胞内,还是在来源于脑肌病病人的组织中,科学家都发现了相同的线粒体tRNA碱基修饰缺陷.通过分子手术证实,此类碱基修饰对于维持这两种tRNA的反密码子与mRNA上相应密码子的相互识别至关重要,缺失了这种修饰的tRNA将无法识别一些对应的密码子.通过进一步的实验,人们还鉴定出负责催化此类碱基修饰的酶.这些研究不但揭示了线粒体遗传性脑肌病相关突变的致病机理,也将为研究基因治疗提供可能的新手段.     

Pathology-related mutation A7526G (A9G) helps in the understanding of the 3D structural core of human mitochondrial tRNAAsp

More than 130 mutations in human mitochondrial tRNA (mt-tRNA) genes have been correlated with a variety of neurodegenerative and neuromuscular disorders. Their molecular impacts are of mosaic type, affecting various stages of tRNA biogenesis, structure, and/or functions in mt-translation. Knowledge of mammalian mt-tRNA structures per se remains scarce however. Primary and secondary structures deviate from classical tRNAs, while rules for three-dimensional (3D) folding are almost unknown. Here, we take advantage of a myopathy-related mutation A7526G (A9G) in mt-tRNA^Asp to investigate both the primary molecular impact underlying the pathology and the role of nucleotide 9 in the network of 3D tertiary interactions. Experimental evidence is presented for existence of a 9-12-23 triple in human mt-tRNA^Asp with a strongly conserved interaction scheme in mammalian mt-tRNAs. Mutation A7526G disrupts the triple interaction and in turn reduces aspartylation efficiency.     

Pathogenic mutations in antisense mitochondrial tRNAs

Pathogenic mutations in mitochondrial tRNAs are 6.5 times more frequent than in other mitochondrial genes. This suggests that tRNA mutations perturb more than one function. A potential additional tRNA gene function is that of templating for antisense tRNAs. Pathogenic mutations weaken cloverleaf secondary structures of sense tRNAs. Analyses here show similar effects for most antisense tRNAs, especially after adjusting for associations between sense and antisense cloverleaf stabilities. These results imply translational activity by antisense tRNAs. For sense tRNAs Ala and Ser UCN, pathogenicity associates as much with sense as with antisense cloverleaf formation. For tRNA Pro, pathogenicity seems associated only with antisense, not sense tRNA cloverleaf formation. Translational activity by antisense tRNAs is expected for the 11 antisense tRNAs processed by regular sense RNA maturation, those recognized by their cognate amino acid’s tRNA synthetase, and those forming relatively stable cloverleaves as compared to their sense counterpart. Most antisense tRNAs probably function routinely in translation and extend the tRNA pool (extension hypothesis); others do not (avoidance hypothesis). The greater the expected translational activity of an antisense tRNA, the more pathogenic mutations weaken its cloverleaf secondary structure. Some evidence for RNA interference, a more classical role for antisense tRNAs, exists only for tRNA Ser UCN. Mutation pathogenicity probably frequently results from a mixture of effects due to sense and antisense tRNA translational activity for many mitochondrial tRNAs. Genomic studies should routinely explore for translational activity by antisense tRNAs.     

Parallel evolution of truncated transfer RNA genes in arachnid mitochondrial genomes

The cloverleaf secondary structure of transfer RNA (tRNA) is highly conserved across all forms of life. Here, we provide sequence data and inferred secondary structures for all tRNA genes from 8 new arachnid mitochondrial genomes, including representatives from 6 orders. These data show remarkable reductions in tRNA gene sequences, indicating that T-arms are missing from many of the 22 tRNAs in the genomes of 4 out of 7 orders of arachnids. Additionally, all opisthothele spiders possess some tRNA genes that lack sequences that could form well-paired aminoacyl acceptor stems. We trace the evolution of T-arm loss onto phylogenies of arachnids and show that a genome-wide propensity to lose sequences that encode canonical cloverleaf structures likely evolved multiple times within arachnids. Mapping of structural characters also shows that certain tRNA genes appear more evolutionarily prone to lose the sequence coding for the T-arm and that once a T-arm is lost, it is not regained. We use tRNA structural data to construct a phylogeny of arachnids and find high bootstrap support for a clade that is not supported in phylogenies that are based on more traditional morphological characters. Together, our data demonstrate variability in structural evolution among different tRNAs as well as evidence for parallel evolution of the loss of sequence coding for tRNA arms within an ancient and diverse group of animals.     

Two ancient bacterial endosymbionts have coevolved with the planthoppers (Insecta: Hemiptera: Fulgoroidea)

Background

Pseudoscorpions are chelicerates and have historically been viewed as being most closely related to solifuges, harvestmen, and scorpions. No mitochondrial genomes of pseudoscorpions have been published, but the mitochondrial genomes of some lineages of Chelicerata possess unusual features, including short rRNA genes and tRNA genes that lack sequence to encode arms of the canonical cloverleaf-shaped tRNA. Additionally, some chelicerates possess an atypical guanine-thymine nucleotide bias on the major coding strand of their mitochondrial genomes.

Results

We sequenced the mitochondrial genomes of two divergent taxa from the chelicerate order Pseudoscorpiones. We find that these genomes possess unusually short tRNA genes that do not encode cloverleaf-shaped tRNA structures. Indeed, in one genome, all 22 tRNA genes lack sequence to encode canonical cloverleaf structures. We also find that the large ribosomal RNA genes are substantially shorter than those of most arthropods. We inferred secondary structures of the LSU rRNAs from both pseudoscorpions, and find that they have lost multiple helices. Based on comparisons with the crystal structure of the bacterial ribosome, two of these helices were likely contact points with tRNA T-arms or D-arms as they pass through the ribosome during protein synthesis. The mitochondrial gene arrangements of both pseudoscorpions differ from the ancestral chelicerate gene arrangement. One genome is rearranged with respect to the location of protein-coding genes, the small rRNA gene, and at least 8 tRNA genes. The other genome contains 6 tRNA genes in novel locations. Most chelicerates with rearranged mitochondrial genes show a genome-wide reversal of the CA nucleotide bias typical for arthropods on their major coding strand, and instead possess a GT bias. Yet despite their extensive rearrangement, these pseudoscorpion mitochondrial genomes possess a CA bias on the major coding strand. Phylogenetic analyses of all 13 mitochondrial protein-coding gene sequences consistently yield trees that place pseudoscorpions as sister to acariform mites.

Conclusion

The well-supported phylogenetic placement of pseudoscorpions as sister to Acariformes differs from some previous analyses based on morphology. However, these two lineages share multiple molecular evolutionary traits, including substantial mitochondrial genome rearrangements, extensive nucleotide substitution, and loss of helices in their inferred tRNA and rRNA structures.     

Tissue-specific expression atlas of murine mitochondrial tRNAs

Mammalian mitochondrial tRNA (mt-tRNA) plays a central role in the synthesis of the 13 subunits of the oxidative phosphorylation complex system (OXPHOS). However, many aspects of the context-dependent expression of mt-tRNAs in mammals remain unknown. To investigate the tissue-specific effects of mt-tRNAs, we performed a comprehensive analysis of mitochondrial tRNA expression across five mice tissues (brain, heart, liver, skeletal muscle, and kidney) using Northern blot analysis. Striking differences in the tissue-specific expression of 22 mt-tRNAs were observed, in some cases differing by as much as tenfold from lowest to highest expression levels among these five tissues. Overall, the heart exhibited the highest levels of mt-tRNAs, while the liver displayed markedly lower levels. Variations in the levels of mt-tRNAs showed significant correlations with total mitochondrial DNA (mtDNA) contents in these tissues. However, there were no significant differences observed in the 2-thiouridylation levels of tRNA^Lys, tRNA^Glu, and tRNA^Gln among these tissues. A wide range of aminoacylation levels for 15 mt-tRNAs occurred among these five tissues, with skeletal muscle and kidneys most notably displaying the highest and lowest tRNA aminoacylation levels, respectively. Among these tissues, there was a negative correlation between variations in mt-tRNA aminoacylation levels and corresponding variations in mitochondrial tRNA synthetases (mt-aaRS) expression levels. Furthermore, the variable levels of OXPHOS subunits, as encoded by mtDNA or nuclear genes, may reflect differences in relative functional emphasis for mitochondria in each tissue. Our findings provide new insight into the mechanism of mt-tRNA tissue-specific effects on oxidative phosphorylation.     

草鱼(Ctenopharyngodon idellus)线粒体DNA控制区及其两侧tRNA基因的克隆与结构分析

动物线粒体ＤＮＡ控制区是线粒体基因组复制与基因表达的最主要的调控区．采用杂交和测序的方法对草鱼线粒体ＤＮＡ控制区进行定位、克隆并测定了控制区及其旁侧的ｔＲＮＡＰｈｅ、ｒＲＮＡＰｒｏ和ｒＲＮＡＴｈｒ三个基因的序列,与多种脊椎动物的相应序列进行了比较,并进行了结构分析．草鱼线粒体控制区全长９２７ｂｐ,含有与酵母和爪蟾线粒体启动子相似的序列,其ＣＳＢⅠ、ＣＳＢⅡ和ＣＳＢⅢ序列与其他几种动物的ＣＳＢ比较相当保守,ＴＡＳ与其回文基序可形成稳定的茎环结构,成为Ｈ－链复制的终止信号．草鱼线粒体ｔＲＮＡＰｈｅ、ｔＲＮＡＰｒｏ和ｔＲＮＡＴｈｒ可折叠成三叶草形二级结构,其基因具有许多不同于细胞质ｔＲＮＡ基因的结构特点,可能反映了线粒体ｔＲＮＡ与线粒体核糖体具有不寻常的作用方式     

tRNA转录后修饰的功能及其与人类疾病的关系

转移核糖核酸(tRNA)的转录后修饰对tRNA正常行使生物学功能具有重要意义,这些功能包括tRNA的正确折叠和维持其稳定性、在核糖体上正确解码。虽然tRNA转录后大部分核苷酸修饰形式在20世纪70年代已被鉴定出,但最近才在大肠杆菌及酵母中鉴定出催化这些tRNA核苷酸修饰的酶的绝大部分基因。这些修饰酶基因的鉴定为研究tRNA转录后修饰的生物功能开启了新的大门。人胞质tRNA和线粒体tRNA(mt tRNA)都存在大量核苷酸修饰,这些修饰的缺陷常常与多种人类疾病相关。因此,研究tRNA核苷酸修饰有助于我们了解相关疾病的发病机理。     

Mamit-tRNA, a database of mammalian mitochondrial tRNA primary and secondary structures

Mamit-tRNA (http://mamit-tRNA.u-strasbg.fr), a database for mammalian mitochondrial genomes, has been developed for deciphering structural features of mammalian mitochondrial tRNAs and as a helpful tool in the frame of human diseases linked to point mutations in mitochondrial tRNA genes. To accommodate the rapid growing availability of fully sequenced mammalian mitochondrial genomes, Mamit-tRNA has implemented a relational database, and all annotated tRNA genes have been curated and aligned manually. System administrative tools have been integrated to improve efficiency and to allow real-time update (from GenBank Database at NCBI) of available mammalian mitochondrial genomes. More than 3000 tRNA gene sequences from 150 organisms are classified into 22 families according to the amino acid specificity as defined by the anticodon triplets and organized according to phylogeny. Each sequence is displayed linearly with color codes indicating secondary structural domains and can be converted into a printable two-dimensional (2D) cloverleaf structure. Consensus and typical 2D structures can be extracted for any combination of primary sequences within a given tRNA specificity on the basis of phylogenetic relationships or on the basis of structural peculiarities. Mamit-tRNA further displays static individual 2D structures of human mitochondrial tRNA genes with location of polymorphisms and pathology-related point mutations. The site offers also a table allowing for an easy conversion of human mitochondrial genome nucleotide numbering into conventional tRNA numbering. The database is expected to facilitate exploration of structure/function relationships of mitochondrial tRNAs and to assist clinicians in the frame of pathology-related mutation assignments.     

Localization and organization of tRNA genes on the mitochondrial genomes of fertile and male sterile lines of maize

Summary Maize mitochondrial (mt) tRNA genes were localized on the mt master circles of two fertile lines (WF9-N and B37-N) and of one cytoplasmic male sterile line (B37-cmsT) of maize. The three genomes contain 16 tRNA genes with 14 different anticodons which correspond to 13 amino acids. Out of these 16 tRNA genes, 6 show a high degree of homology with the corresponding chloroplast (cp) tRNA genes and were shown to originate from cp DNA insertions and to be expressed in the mitochondria. The organization of the mt tRNA genes in both fertile lines is similar. The same genes are found, in the same environment, as judged from the restriction maps, in fertile and male sterile lines that have the same nuclear background, but the relative organization of the mt tRNA genes on the master circle is completely different.     

A correlation between N2-dimethylguanosine presence and alternate tRNA conformers.

Even though the evolutionary conservation of the cloverleaf model is strongly suggestive of powerful constraints on the secondary structure of functional tRNAs, some mitochondrial tRNAs cannot be folded into this form. From the optimal base pairing pattern of these recalcitrant tRNAs, structural correlations between the length of the anticodon stem and the lengths of connector regions between the two helical domains, formed by the coaxial stacking of the anticodon and D-stems and the acceptor and T-stems, have been derived and used to scan the tRNA and tRNA gene database. We show here that some cytosolic tRNA gene sequences that are compatible with the cloverleaf model can also be folded into patterns proposed for the unusual mitochondrial tRNAs. Furthermore, the ability to be folded into these atypical structures correlates in the mature RNA sequences with the presence of dimethylguanosine, whose role may be to prevent the unusual mitochondrial tRNA pattern folding.     

Search for characteristic structural features of mammalian mitochondrial tRNAs

A number of mitochondrial (mt) tRNAs have strong structural deviations from the classical tRNA cloverleaf secondary structure and from the conventional L-shaped tertiary structure. As a consequence, there is a general trend to consider all mitochondrial tRNAs as "bizarre" tRNAs. Here, a large sequence comparison of the 22 tRNA genes within 31 fully sequenced mammalian mt genomes has been performed to define the structural characteristics of this specific group of tRNAs. Vertical alignments define the degree of conservation/variability of primary sequences and secondary structures and search for potential tertiary interactions within each of the 22 families. Further horizontal alignments ascertain that, with the exception of serine-specific tRNAs, mammalian mt tRNAs do fold into cloverleaf structures with mostly classical features. However, deviations exist and concern large variations in size of the D- and T-loops. The predominant absence of the conserved nucleotides G18G19 and T54T55C56, respectively in these loops, suggests that classical tertiary interactions between both domains do not take place. Classification of the tRNA sequences according to their genomic origin (G-rich or G-poor DNA strand) highlight specific features such as richness/poorness in mismatches or G-T pairs in stems and extremely low G-content or C-content in the D- and T-loops. The resulting 22 "typical" mammalian mitochondrial sequences built up a phylogenetic basis for experimental structural and functional investigations. Moreover, they are expected to help in the evaluation of the possible impacts of those point mutations detected in human mitochondrial tRNA genes and correlated with pathologies.     

Assigning pathogenicity to mitochondrial tRNA mutations: when "definitely maybe" is not good enough

Some mutations in mitochondrial tRNA (mt-tRNA) genes cause devastating disease, whereas others have no clinical consequences. We understand little of the factors determining the pathogenicity of specific mt-tRNA mutations, making prediction of clinical outcome extremely difficult. Using extensive sequence databases, we compared the characteristics of neutral variations with those of pathogenic mutations. We recommend that the location of the proposed mutation within the secondary structure of the mt-tRNA molecule and the disruption it causes to Watson-Crick base pairing should be considered when assessing the pathological significance of a novel mt-tRNA mutation.     

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.