scholarly journals Human ERAL1 is a mitochondrial RNA chaperone involved in the assembly of the 28S small mitochondrial ribosomal subunit

2010 ◽  
Vol 430 (3) ◽  
pp. 551-558 ◽  
Author(s):  
Sven Dennerlein ◽  
Agata Rozanska ◽  
Mateusz Wydro ◽  
Zofia M. A. Chrzanowska-Lightowlers ◽  
Robert N. Lightowlers
Keyword(s):  
16S Rrna ◽  
Cellular Localization ◽  
Mitochondrial Protein ◽  
Ribosomal Subunit ◽  
Small Subunit ◽  
Mitochondrial Rna ◽  
Rna Chaperone ◽  
Stem Loop ◽  
Loop Region

The bacterial Ras-like protein Era has been reported previously to bind 16S rRNA within the 30S ribosomal subunit and to play a crucial role in ribosome assembly. An orthologue of this essential GTPase ERAL1 (Era G-protein-like 1) exists in higher eukaryotes and although its exact molecular function and cellular localization is unknown, its absence has been linked to apoptosis. In the present study we show that human ERAL1 is a mitochondrial protein important for the formation of the 28S small mitoribosomal subunit. We also show that ERAL1 binds in vivo to the rRNA component of the small subunit [12S mt (mitochondrial)-rRNA]. Bacterial Era associates with a 3′ unstructured nonanucleotide immediately downstream of the terminal stem–loop (helix 45) of 16S rRNA. This site contains an AUCA sequence highly conserved across all domains of life, immediately upstream of the anti-Shine–Dalgarno sequence, which is conserved in bacteria. Strikingly, this entire region is absent from 12S mt-rRNA. We have mapped the ERAL1-binding site to a 33 nucleotide section delineating the 3′ terminal stem–loop region of 12S mt-rRNA. This loop contains two adenine residues that are reported to be dimethylated on mitoribosome maturation. Furthermore, and also in contrast with the bacterial orthologue, loss of ERAL1 leads to rapid decay of nascent 12S mt-rRNA, consistent with a role as a mitochondrial RNA chaperone. Finally, whereas depletion of ERAL1 leads to apoptosis, cell death occurs prior to any appreciable loss of mitochondrial protein synthesis or reduction in the stability of mitochondrial mRNA.

scholarly journals The human mitochondrial 12S rRNA m4C methyltransferase METTL15 is required for proper mitochondrial function

2019 ◽  
Author(s):  
Hao Chen ◽  
Zhennan Shi ◽  
Jiaojiao Guo ◽  
Kao-jung Chang ◽  
Qianqian Chen ◽  
...  
Keyword(s):  
Mitochondrial Protein ◽  
Small Subunit ◽  
12S Rrna ◽  
Mitochondrial Rna ◽  
Protein Coding ◽  
Mitochondrial Ribosome ◽  
The Difference ◽  
And Function

ABSTRACTMitochondrial DNA (mtDNA) gene expression is coordinately regulated pre- and post-transcriptionally, and its perturbation can lead to human pathologies. Mitochondrial ribosomal RNAs (mt-rRNAs) undergo a series of nucleotide modifications following release from polycistronic mitochondrial RNA (mtRNA) precursors, which is essential for mitochondrial ribosomal biogenesis. Cytosine N4 methylation (m4C) at position 839 of the 12S small subunit (SSU) mt-rRNA was identified decades ago, however, its biogenesis and function have not been elucidated in details. Here we demonstrate that human Methyltransferase Like 15 (METTL15) is responsible for 12S mt-rRNA methylation at C839 (m4C839) both in vivo and in vitro. We tracked the evolutionary history of RNA m4C methyltransferases and revealed the difference in substrates preference between METTL15 and its bacterial ortholog rsmH. Additionally, unlike the very modest impact on ribosome upon loss of m4C methylation in bacterial SSU rRNA, we found that depletion of METTL15 specifically causes severe defects in mitochondrial ribosome assembly, which leads to an impaired translation of mitochondrial protein-coding genes and a decreased mitochondrial respiration capacity. Our findings point to a co-evolution of methylatransferase specificities and modification patterns in rRNA with differential impact on prokaryotic ribosome versus eukaryotic mitochondrial ribosome.

scholarly journals The human mitochondrial 12S rRNA m4C methyltransferase METTL15 is required for mitochondrial function

2020 ◽  
Vol 295 (25) ◽  
pp. 8505-8513 ◽  
Author(s):  
Hao Chen ◽  
Zhennan Shi ◽  
Jiaojiao Guo ◽  
Kao-jung Chang ◽  
Qianqian Chen ◽  
...  
Keyword(s):  
Mitochondrial Function ◽  
Mitochondrial Protein ◽  
Nuclear Gene ◽  
Small Subunit ◽  
12S Rrna ◽  
Mitochondrial Rna ◽  
Small Subunit Rrna ◽  
Mitochondrial Ribosomes

Mitochondrial DNA gene expression is coordinately regulated both pre- and post-transcriptionally, and its perturbation can lead to human pathologies. Mitochondrial rRNAs (mt-rRNAs) undergo a series of nucleotide modifications after release from polycistronic mitochondrial RNA precursors, which is essential for mitochondrial ribosomal biogenesis. Cytosine N4-methylation (m4C) at position 839 (m4C839) of the 12S small subunit mt-rRNA was identified decades ago; however, its biogenesis and function have not been elucidated in detail. Here, using several approaches, including immunofluorescence, RNA immunoprecipitation and methylation assays, and bisulfite mapping, we demonstrate that human methyltransferase-like 15 (METTL15), encoded by a nuclear gene, is responsible for 12S mt-rRNA methylation at m4C839 both in vivo and in vitro. We tracked the evolutionary history of RNA m4C methyltransferases and identified a difference in substrate preference between METTL15 and its bacterial ortholog rsmH. Additionally, unlike the very modest impact of a loss of m4C methylation in bacterial small subunit rRNA on the ribosome, we found that METTL15 depletion results in impaired translation of mitochondrial protein-coding mRNAs and decreases mitochondrial respiration capacity. Our findings reveal that human METTL15 is required for mitochondrial function, delineate the evolution of methyltransferase substrate specificities and modification patterns in rRNA, and highlight a differential impact of m4C methylation on prokaryotic ribosomes and eukaryotic mitochondrial ribosomes.

scholarly journals Circumstances and mechanisms of inhibition of translation by secondary structure in eucaryotic mRNAs.

1989 ◽  
Vol 9 (11) ◽  
pp. 5134-5142 ◽  
Author(s):  
M Kozak
Keyword(s):  
Secondary Structure ◽  
Ribosomal Subunit ◽  
Loop Structure ◽  
Entry Site ◽  
Range Interaction ◽  
Stem Loop ◽  
Stem Loop Structure ◽  
Delta G

This paper describes in vitro experiments with two types of intramolecular duplex structures that inhibit translation in cis by preventing the formation of an initiation complex or by causing the complex to be abortive. One stem-loop structure (delta G = -30 kcal/mol) prevented mRNA from engaging 40S subunits when the hairpin occurred 12 nucleotides (nt) from the cap but had no deleterious effect when it was repositioned 52 nt from the cap. This result confirms prior in vivo evidence that the 40S subunit-factor complex, once bound to mRNA, has considerable ability to penetrate secondary structure. Consequently, translation is most sensitive to secondary structure at the entry site for ribosomes, i.e., the 5' end of the mRNA. The second stem-loop structure (hp7; delta G = -61 kcal/mol, located 72 nt from the cap) was too stable to be unwound by 40S ribosomes, hp7 did not prevent a 40S ribosomal subunit from binding but caused the 40S subunit to stall on the 5' side of the hairpin, exactly as the scanning model predicts. Control experiments revealed that 80S elongating ribosomes could disrupt duplex structures, such as hp7, that were too stable to be penetrated by the scanning 40S ribosome-factor complex. A third type of base-paired structure shown to inhibit translation in vivo involves a long-range interaction between the 5' and 3' noncoding sequences.

Circumstances and mechanisms of inhibition of translation by secondary structure in eucaryotic mRNAs

1989 ◽  
Vol 9 (11) ◽  
pp. 5134-5142
Author(s):  
M Kozak
Keyword(s):  
Secondary Structure ◽  
Ribosomal Subunit ◽  
Loop Structure ◽  
Entry Site ◽  
Range Interaction ◽  
Stem Loop ◽  
Stem Loop Structure ◽  
Delta G

This paper describes in vitro experiments with two types of intramolecular duplex structures that inhibit translation in cis by preventing the formation of an initiation complex or by causing the complex to be abortive. One stem-loop structure (delta G = -30 kcal/mol) prevented mRNA from engaging 40S subunits when the hairpin occurred 12 nucleotides (nt) from the cap but had no deleterious effect when it was repositioned 52 nt from the cap. This result confirms prior in vivo evidence that the 40S subunit-factor complex, once bound to mRNA, has considerable ability to penetrate secondary structure. Consequently, translation is most sensitive to secondary structure at the entry site for ribosomes, i.e., the 5' end of the mRNA. The second stem-loop structure (hp7; delta G = -61 kcal/mol, located 72 nt from the cap) was too stable to be unwound by 40S ribosomes, hp7 did not prevent a 40S ribosomal subunit from binding but caused the 40S subunit to stall on the 5' side of the hairpin, exactly as the scanning model predicts. Control experiments revealed that 80S elongating ribosomes could disrupt duplex structures, such as hp7, that were too stable to be penetrated by the scanning 40S ribosome-factor complex. A third type of base-paired structure shown to inhibit translation in vivo involves a long-range interaction between the 5' and 3' noncoding sequences.

Mutually exclusive synthetic pathways for sea urchin mitochondrial rRNA and mRNA

1989 ◽  
Vol 9 (3) ◽  
pp. 1069-1082
Author(s):  
D J Elliott ◽  
H T Jacobs
Keyword(s):  
16S Rrna ◽  
Sea Urchin ◽  
Large Subunit ◽  
Blot Hybridization ◽  
Small Subunit ◽  
12S Rrna ◽  
Mitochondrial Rna ◽  
Coding Region ◽  
Alternative Processing ◽  
Nadh Dehydrogenase Subunit 2

The structure and abundance of mitochondrial transcripts in sea urchin embryos were investigated by a combination of RNA blot-hybridization, S1 mapping, and primer extension assays. Between the egg and blastula stages, the relative abundance of mitochondrial rRNAs declined slightly, while that of mitochondrial mRNAs increased up to 10-fold. Fine mapping of the termini of the rRNAs and of the adjacent transcripts indicated that, although they appeared to be butt-joined at their 5' ends to the upstream transcripts, tRNA-Phe 5' to the small subunit (12S) rRNA and NADH dehydrogenase subunit 2 mRNA 5' to the large subunit (16S) rRNA, respectively, their 3' ends were found to overlap the 5' ends of the downstream transcripts. 12S rRNA was found to extend 7 to 13 nucleotides into the sequence of tRNA-Glu; 16S rRNA was shown to terminate 3 to 5 nucleotides inside the coding region of cytochrome oxidase subunit 1 (COI) and 8 to 10 nucleotides from the mapped 5' end of COI mRNA. The rRNAs and the downstream transcripts must therefore be synthesized by distinct pathways, either by alternative processing of the same primary transcript(s) or by processing of different precursors. In either case, the events which select the ribosomal 3' ends preclude the production of functional transcripts of the downstream genes from the same precursor molecule. No developmental alterations in transcript structure were detected. We propose that mitochondrial RNA levels are regulated in early development by the selection of alternate and mutually exclusive RNA-processing pathways.

An oligonucleotide analog approach to the decoding region of 16S rRNA

1995 ◽  
Vol 73 (11-12) ◽  
pp. 899-905 ◽  
Author(s):  
Seth Stern ◽  
Prakash Purohit
Keyword(s):  
16S Rrna ◽  
Ribosomal Rna ◽  
Molecular Basis ◽  
Ribosomal Subunit ◽  
Small Subunit ◽  
16S Ribosomal Rna ◽  
New Approach ◽  
16S Rna ◽  
Analog Approach ◽  
Decoding Region

Despite the passage of about 30 years since the discovery of the translational activities of ribosomes and the outlining of the roles of the large and small subunits, the actual molecular basis for the mRNA decoding activities of the small subunit has remained essentially obscure. In this paper, we describe a new approach using oligonucleotide analogs of 16S ribosomal RNA, in which the small ribosomal subunit is effectively deconstructed into a smaller more experimentally tractable form. Specifically, we review the results of experiments using an oligonucleotide analog of the decoding region of 16S ribosomal RNA, suggesting that the decoding region is the functional core of the small subunit, that it contacts both mRNA codons and tRNA anticodons, and that it mediates and probably enhances codon–anticodon base pairing, that is, decoding.Key words: translation, ribosome, 30S, 16S, RNA, decoding, antibiotic.

scholarly journals The methyltransferase adaptor protein Trm112 is involved in biogenesis of both ribosomal subunits

2012 ◽  
Vol 23 (21) ◽  
pp. 4313-4322 ◽  
Author(s):  
Richa Sardana ◽  
Arlen W. Johnson
Keyword(s):  
Slow Growth ◽  
Ribosomal Subunit ◽  
Adaptor Protein ◽  
Small Subunit ◽  
Stable Complex ◽  
Sedimentation Analysis ◽  
Ribosomal Subunits ◽  
Translation Factors ◽  
40S Ribosomal Subunit

We previously identified Bud23 as the methyltransferase that methylates G1575 of rRNA in the P-site of the small (40S) ribosomal subunit. In this paper, we show that Bud23 requires the methyltransferase adaptor protein Trm112 for stability in vivo. Deletion of Trm112 results in a bud23Δ-like mutant phenotype. Thus Trm112 is required for efficient small-subunit biogenesis. Genetic analysis suggests the slow growth of a trm112Δ mutant is due primarily to the loss of Bud23. Surprisingly, suppression of the bud23Δ-dependent 40S defect revealed a large (60S) biogenesis defect in a trm112Δ mutant. Using sucrose gradient sedimentation analysis and coimmunoprecipitation, we show that Trm112 is also involved in 60S subunit biogenesis. The 60S defect may be dependent on Nop2 and Rcm1, two additional Trm112 interactors that we identify. Our work extends the known range of Trm112 function from modification of tRNAs and translation factors to both ribosomal subunits, showing that its effects span all aspects of the translation machinery. Although Trm112 is required for Bud23 stability, our results suggest that Trm112 is not maintained in a stable complex with Bud23. We suggest that Trm112 stabilizes its free methyltransferase partners not engaged with substrate and/or helps to deliver its methyltransferase partners to their substrates.

scholarly journals Reading canonical and modified nucleotides in 16S ribosomal RNA using nanopore direct RNA sequencing

2017 ◽  
Author(s):  
Andrew M. Smith ◽  
Miten Jain ◽  
Logan Mulroney ◽  
Daniel R. Garalde ◽  
Mark Akeson
Keyword(s):  
16S Rrna ◽  
Rna Sequencing ◽  
Ionic Current ◽  
Ribosomal Subunit ◽  
Small Subunit ◽  
Rapid Identification ◽  
Rrna Genes ◽  
Aminoglycoside Resistance ◽  
Base Pairs ◽  
E Coli

The ribosome small subunit is expressed in all living cells. It performs numerous essential functions during translation, including formation of the initiation complex and proofreading of base-pairs between mRNA codons and tRNA anticodons. The core constituent of the small ribosomal subunit is a ∼1.5 kb RNA strand in prokaryotes (16S rRNA) and a homologous ∼1.8 kb RNA strand in eukaryotes (18S rRNA). Traditional sequencing-by-synthesis (SBS) of rRNA genes or rRNA cDNA copies has achieved wide use as a ‘molecular chronometer’ for phylogenetic studies 1, and as a tool for identifying infectious organisms in the clinic 2. However, epigenetic modifications on rRNA are erased by SBS methods. Here we describe direct MinION nanopore sequencing of individual, full-length 16S rRNA absent reverse transcription or amplification. As little as 5 picograms (∼10 attomole) of E. coli 16S rRNA was detected in 4.5 micrograms of total human RNA. Nanopore ionic current traces that deviated from canonical patterns revealed conserved 16S rRNA base modifications, and a 7-methylguanosine modification that confers aminoglycoside resistance to some pathological E. coli strains. This direct RNA sequencing technology has promise for rapid identification of microbes in the environment and in patient samples.

scholarly journals Mutually exclusive synthetic pathways for sea urchin mitochondrial rRNA and mRNA.

1989 ◽  
Vol 9 (3) ◽  
pp. 1069-1082 ◽  
Author(s):  
D J Elliott ◽  
H T Jacobs
Keyword(s):  
16S Rrna ◽  
Sea Urchin ◽  
Large Subunit ◽  
Blot Hybridization ◽  
Small Subunit ◽  
12S Rrna ◽  
Mitochondrial Rna ◽  
Coding Region ◽  
Alternative Processing ◽  
Nadh Dehydrogenase Subunit 2

The structure and abundance of mitochondrial transcripts in sea urchin embryos were investigated by a combination of RNA blot-hybridization, S1 mapping, and primer extension assays. Between the egg and blastula stages, the relative abundance of mitochondrial rRNAs declined slightly, while that of mitochondrial mRNAs increased up to 10-fold. Fine mapping of the termini of the rRNAs and of the adjacent transcripts indicated that, although they appeared to be butt-joined at their 5' ends to the upstream transcripts, tRNA-Phe 5' to the small subunit (12S) rRNA and NADH dehydrogenase subunit 2 mRNA 5' to the large subunit (16S) rRNA, respectively, their 3' ends were found to overlap the 5' ends of the downstream transcripts. 12S rRNA was found to extend 7 to 13 nucleotides into the sequence of tRNA-Glu; 16S rRNA was shown to terminate 3 to 5 nucleotides inside the coding region of cytochrome oxidase subunit 1 (COI) and 8 to 10 nucleotides from the mapped 5' end of COI mRNA. The rRNAs and the downstream transcripts must therefore be synthesized by distinct pathways, either by alternative processing of the same primary transcript(s) or by processing of different precursors. In either case, the events which select the ribosomal 3' ends preclude the production of functional transcripts of the downstream genes from the same precursor molecule. No developmental alterations in transcript structure were detected. We propose that mitochondrial RNA levels are regulated in early development by the selection of alternate and mutually exclusive RNA-processing pathways.

scholarly journals MTG1 Codes for a Conserved Protein Required for Mitochondrial Translation

2003 ◽  
Vol 14 (6) ◽  
pp. 2292-2302 ◽  
Author(s):  
Antoni Barrientos ◽  
Daniel Korr ◽  
Karen J. Barwell ◽  
Christian Sjulsen ◽  
Carl D. Gajewski ◽  
...  
Keyword(s):  
Mitochondrial Protein ◽  
Ribosomal Subunit ◽  
Temperature Sensitive ◽  
Large Ribosomal Subunit ◽  
Human Homologue ◽  
Mitochondrial Translation ◽  
Respiratory Deficiency ◽  
The Matrix ◽  
Mature Size

The MTG1 gene of Saccharomyces cerevisiae, corresponding to ORF YMR097c on chromosome XIII, codes for a mitochondrial protein essential for respiratory competence. A human homologue of Mtg1p capable of partially rescuing the respiratory deficiency of a yeast mtg1 mutant has also been localized in mitochondria. Mtg1p is a member of a family of GTPases with largely unknown functions. The respiratory deficiency of mtg1 mutants stems from a defect in mitochondrial protein synthesis. Mutations in the 21S rRNA locus are able to suppress the translation defect of mtg1 null mutants. This points to the 21S rRNA or the large ribosomal subunit as the most likely target of Mtg1p action. The presence of mature size 15S and 21S mitochondrial rRNAs in mtg1 mutants excludes Mtg1p from being involved in transcription or processing of these RNAs. More likely, Mtg1p functions in assembly of the large ribosomal subunit. This is consistent with the peripheral localization of Mtg1p on the matrix side of the inner membrane and the results of in vivo mitochondrial translation assays in a temperature-sensitive mtg1 mutant.

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