A tRNA suppressor mutation in human mitochondria.

Mitochondrial mutations are associated with a wide spectrum of human diseases. A common class of point mutations affects tRNA genes, and mutations in the tRNA-leu(UUR) gene (MTTL1) are the most frequently detected. In earlier studies, we showed that lung carcinoma cybrid cells containing high levels (greater than 95%) of mutated mtDNA from a patient with the pathological nucleotide pair (np) 3243 tRNA-leu(UUR) mutation can remain genotypically stable over time, and exhibit severe defects in mitochondrial respiratory metabolism. From such a cybrid containing 99% mutated mtDNA, we have isolated a spontaneous derivative that retains mutant mtDNA at this level but which has nevertheless reverted to the wild-type phenotype, based on studies of respiration, growth in selective media, mitochondrial protein synthesis and biogenesis of mitochondrial membrane complexes. The cells are heteroplasmic for a novel anticodon mutation in tRNA-leu(CUN) at np 12300, predicted to generate a suppressor tRNA capable of decoding UUR leucine codons. The suppressor mutation represents approximately 10% of the total mtDNA, but was undetectable in a muscle biopsy sample taken from the original patient or in the parental cybrid. These results indicate that the primary biochemical defect in cells with high levels of np 3243 mutated mtDNA is the inability to translate UUR leucine codons.

Human mitochondrial DNA deletions associated with mutations in the gene encoding Twinkle, a phage T7 gene 4-like protein localized in mitochondria.

The gene products involved in mammalian mitochondrial DNA (mtDNA) maintenance and organization remain largely unknown. We report here a novel mitochondrial protein, Twinkle, with structural similarity to phage T7 gene 4 primase/helicase and other hexameric ring helicases. Twinkle colocalizes with mtDNA in mitochondrial nucleoids. Screening of the gene encoding Twinkle in individuals with autosomal dominant progressive external ophthalmoplegia (adPEO), associated with multiple mtDNA deletions, identified 11 different coding-region mutations co-segregating with the disorder in 12 adPEO pedigrees of various ethnic origins. The mutations cluster in a region of the protein proposed to be involved in subunit interactions. The function of Twinkle is inferred to be critical for lifetime maintenance of human mtDNA integrity.

Mutations at the mitochondrial DNA polymerase (POLG) locus associated with male infertility.

Human mitochondrial DNA polymerase, encoded by POLG, contains a polyglutamine tract encoded by a CAG microsatellite repeat. Analysis of POLG genotypes in different populations identified an association between absence of the common, ten-repeat allele and male infertility typified by a range of sperm quality defects but excluding azoospermia.

Making mitochondrial mutants.

Mitochondrial DNA (mtDNA) encodes a mere 13 polypeptides, all with well-defined cellular functions in mitochondrial energy metabolism. It was first sequenced over two decades ago, yet our understanding of the wider physiological role of mtDNA is surprisingly sketchy. Partly, this reflects the fact that the mitochondrial gene products are essential for life; that is, most mtDNA mutations are expected to be lethal. The technical difficulty of engineering mtDNA mutations has been a major handicap in furthering our understanding of the mitochondrial genetic system. Recent developments now offer some possibilities for the genetic manipulation of mtDNA and for elucidating its contribution to human development, physiology and disease.

Mitochondrial DNA--all things bad?

Mutations in mitochondrial DNA (mtDNA) are undoubtedly associated with a diverse spectrum of human disorders. More controversially, it has been claimed that they accumulate during ageing, and that they are responsible for an age-related decline in bioenergetic function and tissue viability. Here, we review the evidence for this assertion, concluding that claims for the age-accumulation of mtDNA mutations are based largely on non-quantitative methods, and that no clear, functional deficit of mitochondrial respiration has been shown to result from such lesions in aged individuals. The mitochondrial theory of ageing, however attractive in principle, is supported by very little hard evidence.

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

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.

Complete nucleotide sequences of the nuclear pseudogenes for cytochrome oxidase subunit I and the large mitochondrial ribosomal RNA in the sea urchin Strongylocentrotus purpuratus.

Nucleotide sequencing of the sea urchin nuclear genomic homologues of two mitochondrial genes, cytochrome oxidase subunit I (COI) and 16 S ribosomal RNA, shows clearly that they are both pseudogenes. The COI homologue has accumulated numerous single-base changes causing non-conservative amino acid substitutions, as well as many small insertions and deletions, most of which result in frameshifts. There is no continuous open reading frame and eight unmutated TGA codons persist. A genomic repetitive element is found between the break points of two rearrangements that have occurred in the region. By solution hybridization in RNA excess, we were unable to detect transcripts colinear with the complete nuclear COI sequence, using Strongylocentrotus purpuratus gastrula RNA, at a detection limit of 10(-6) of total RNA. Transcripts restricted to the 3' end of the COI pseudogene may be present, however, but at an extremely low level. Comparison of the 16 S/COI junctions in nuclear and mitochondrial DNA suggests a possible complementary DNA-mediated conversion of the 16 S pseudogene subsequent to its original transposition into nuclear DNA. We have estimated the likely age of the nuclear sequence element from the divergence between nuclear and mitochondrial sequences and from cross-hybridization with the genomes of other sea urchin species. With both methods, an age of more than 30 million years is suggested.

Nucleotide sequence and gene organization of sea urchin mitochondrial DNA.

The 15,650 base-pair mitochondrial genome of the sea urchin Strongylocentrotus purpuratus has been cloned and sequenced. It exhibits a novel organization that suggests the primacy of post-transcriptional gene regulation. The same 13 polypeptides, two rRNAs and 22 tRNAs are encoded as in other animal mitochondrial DNAs, but are organized with extreme economy; non-coding information between genes is almost completely absent, some stop codons are generated post-transcriptionally and tRNA sequences are interspersed between only a minority of other structural genes. The genome uses a variant genetic code, in which AAA specifies asparagine, ATA isoleucine, TGA tryptophan and AGN serine, and has an unusual pattern of codon bias. The order of genes shows several differences from that of vertebrates. The genes for the large (16 S) ribosomal RNA and for NADH dehydrogenase subunit 4L (ND4L) are in different positions, located respectively between those encoding ND2 and cytochrome oxidase subunit I (COI) and between COI and COII. This organization is conserved amongst at least four regular echinoids diverging by some 225 million years. Most tRNA genes are also in different positions. The only long unassigned sequence in the genome (121 base-pairs) is located within a cluster of 15 tRNA genes. It contains elements resembling some of those found in the displacement (D) loop of vertebrate mtDNAs, notably polypurine/polypyrimidine tracts that may play a role in regulating transcription and the initiation of replication. The separation of the ribosomal RNA genes from each other and from the putative control region imposes special demands on the transcription of the genome.

Mitochondrial DNA sequences in the nuclear genome of Strongylocentrotus purpuratus.

Two sea urchin embryo complementary DNA clones representing mitochondrial 16 S ribosomal RNA and cytochrome oxidase subunit I messenger RNA have been characterized. The cloned cDNAs are colinear with sea urchin mitochondrial DNA, and their identification is based on cross-hybridization with known restriction fragments of human mitochondrial DNA, and on nucleotide sequence determinations. The mitochondrial cDNA clones also displayed an unexpected reaction with specific genomic DNA sequences in gel blot hybridizations. Genomic phage lambda recombinants containing sequences hybridizing with the mitochondrial clones were isolated and the arrangement of these sequences was determined. The genomic region studied contains a sequence homologous with the 3' end of the mitochondrial 16 S rRNA gene, flanked on one side by what is possibly a complete copy of the cytochrome oxidase subunit I gene, and on the other by a duplication of a fragment of this gene. The nucleotide sequence divergence between the mitochondrial and nuclear homologues of the cytochrome oxidase subunit I gene varies for different regions of the gene, from about 13% to 25%, while there is about 8% sequence divergence between nuclear and mitochondrial versions of the 3' 16S rRNA sequence. The structure of the genomic mitochondrial sequence homologues indicates that during sea urchin evolution there occurred a germ-line transposition of a fragment of the mitochondrial genome into the nuclear DNA, followed by rearrangements and single nucleotide substitutions.

Genotypic stability, segregation and selection in heteroplasmic human cell lines containing np 3243 mutant mtDNA.

The mitochondrial genotype of heteroplasmic human cell lines containing the pathological np 3243 mtDNA mutation, plus or minus its suppressor at np 12300, has been followed over long periods in culture. Cell lines containing various different proportions of mutant mtDNA remained generally at a consistent, average heteroplasmy value over at least 30 wk of culture in nonselective media and exhibited minimal mitotic segregation, with a segregation number comparable with mtDNA copy number (>/=1000). Growth in selective medium of cells at 99% np 3243 mutant mtDNA did, however, allow the isolation of clones with lower levels of the mutation, against a background of massive cell death. As a rare event, cell lines exhibited a sudden and dramatic diversification of heteroplasmy levels, accompanied by a shift in the average heteroplasmy level over a short period (<8 wk), indicating selection. One such episode was associated with a gain of chromosome 9. Analysis of respiratory phenotype and mitochondrial genotype of cell clones from such cultures revealed that stable heteroplasmy values were generally reestablished within a few weeks, in a reproducible but clone-specific fashion. This occurred independently of any straightforward phenotypic selection at the individual cell-clone level. Our findings are consistent with several alternate views of mtDNA organization in mammalian cells. One model that is supported by our data is that mtDNA is found in nucleoids containing many copies of the genome, which can themselves be heteroplasmic, and which are faithfully replicated. We interpret diversification and shifts of heteroplasmy level as resulting from a reorganization of such nucleoids, under nuclear genetic control. Abrupt remodeling of nucleoids in vivo would have major implications for understanding the developmental consequences of heteroplasmy, including mitochondrial disease phenotype and progression.

Technical knockout, a Drosophila model of mitochondrial deafness.

Mutations in mtDNA-encoded components of the mitochondrial translational apparatus are associated with diverse pathological states in humans, notably sensorineural deafness. To develop animal models of such disorders, we have manipulated the nuclear gene for mitochondrial ribosomal protein S12 in Drosophila (technical knockout, tko). The prototypic mutant tko(25t) exhibits developmental delay, bang sensitivity, impaired male courtship, and defective response to sound. On the basis of a transgenic reversion test, these phenotypes are attributable to a single substitution (L85H) at a conserved residue of the tko protein. The mutant is hypersensitive to doxycyclin, an antibiotic that selectively inhibits mitochondrial protein synthesis, and mutant larvae have greatly diminished activities of mitochondrial redox enzymes and decreased levels of mitochondrial small-subunit rRNA. A second mutation in the tko gene, Q116K, which is predicted to impair the accuracy of mitochondrial translation, results in the completely different phenotype of recessive female sterility, based on three independent transgenic insertions. We infer that the tko(25t) mutant provides a model of mitochondrial hearing impairment resulting from a quantitative deficiency of mitochondrial translational capacity.

Novel coding-region polymorphisms in mitochondrial seryl-tRNA synthetase (SARSM) and mitoribosomal protein S12 (RPMS12) genes in DFNA4 autosomal dominant deafness families.

Two genes for components of the mitochondrial translational apparatus, mitochondrial seryl-tRNA synthetase (SARSM) and mitoribosomal protein S12 (RPMS12) lie adjacent to one another on human chromosome 19, within the critical interval for the autosomal dominant deafness locus DFNA4. Both genes are plausible candidates for DFNA4, based on the fact that deafness mutations in mtDNA have been mapped both to tRNA-ser(UCN) and to the accuracy domain of the small subunit rRNA. We have sequenced the coding regions, proximal promoters, 5' and 3' UTR and splice junctional regions of both genes in two families with DFNA4-linked deafness and in controls. Novel polymorphisms 84425C>T, 83907A>G, 79485T>G, 79406C>T, 71755A>C and 68686C>G (numbered as in GenBank AC011455) were found in one or both families, but none is a plausible disease-causing mutation. Although regulatory mutations affecting either gene could still be involved in the phenotype, structural gene mutations affecting SARSM or RPMS12 can be excluded from consideration as the cause of DFNA4-linked deafness, at least in the families identified thus far.

Analysis of the trinucleotide CAG repeat from the human mitochondrial DNA polymerase gene in healthy and diseased individuals.

The human nuclear gene (POLG) for the catalytic subunit of mitochondrial DNA polymerase (DNA polymerase gamma) contains a trinucleotide CAG microsatellite repeat within the coding sequence. We have investigated the frequency of different repeat-length alleles in populations of diseased and healthy individuals. The predominant allele of 10 CAG repeats was found at a very similar frequency (approximately 88%) in both Finnish and ethnically mixed population samples, with homozygosity close to the equilibrium prediction. Other alleles of between 5 and 13 repeat units were detected, but no larger, expanded alleles were found. A series of 51 British myotonic dystrophy patients showed no significant variation from controls, indicating an absence of generalised CAG repeat instability. Patients with a variety of molecular lesions in mtDNA, including sporadic, clonal deletions, maternally inherited point mutations, autosomally transmitted mtDNA depletion and autosomal dominant multiple deletions showed no differences in POLG trinucleotide repeat-length distribution from controls. These findings rule out POLG repeat expansion as a common pathogenic mechanism in disorders characterised by mitochondrial genome instability.

The relationship between mRNA half-life and gene function in the yeast Saccharomyces cerevisiae.

Saccharomyces cerevisiae (Sc) mRNAs have been described as falling into two major classes with respect to mRNA half-life [Santiago et al., Nucleic Acids Res. 14 (1986) 8347-8360]. We have used DNA sequence analysis to address the functional roles of eleven of the thirteen cDNAs upon which Santiago et al. based their conclusions. Eight had been described as copies of short half-life and five as copies of long-half-life mRNAs. We show here that five members of the short-half-life class encode known Sc cytosolic ribosomal proteins (rp). One further short-half-life cDNA appears to encode a new Sc rp related to higher eukaryotic rp S12. Among the long-half-life cDNAs, one encodes the glucose-inducible glycolytic enzyme enolase, while another is related to the mouse housekeeping gene MER5.

Metazoan nuclear genes for mitoribosomal protein S12.

We have characterized nuclear genes for mitoribosomal protein S12 (mt-rps12) a major component of the ribosomal accuracy centre, in human, mouse and Drosophila melanogaster. In human and Drosophila, and probably also in mouse, there is a single intron within the coding region, located in the mitochondrial targeting pre-sequence. In humans, the mRNA structure is highly suggestive of translational regulation. In all three species, there is an amino-acid substitution with respect to eubacterial homologues in a residue implicated in aminoglycoside resistance. The only viable mutant allele of the Drosophila gene, associated with a bang-sensitive phenotype (paralysis upon mechanical vibration, arising from a mechanoreceptor cell defect) also has a novel substitution in a conserved region implicated in translational fidelity. Given the involvement of the mitoribosomal accuracy centre in human sensorineural deafness by virtue of rRNA mutations, our results indicate that this fly mutant may be a useful animal model of this disorder, and earmark the gene for mt-rps12 as a candidate in human hearing impairment.

The mitochondrial inner membrane AAA metalloprotease family in metazoans.

Three metalloproteases belonging to the AAA superfamily (Yme1p, Afg3p and Rca1p) are involved in protein turnover and respiratory chain complex assembly in the yeast inner mitochondrial membrane. Analysis of the completed genome sequences of Caenorhabditis elegans and Drosophila melanogaster indicates that this gene family typically comprises 3-4 members in metazoans. Phylogenetic analysis reveals three main branches represented, respectively, by Saccharomyces cerevisiae YME1, human SPG7 (paraplegin) and S. cerevisiae AFG3 and RCA1. mt-AAA metalloproteases are weak candidates for several previously studied Drosophila mutants. A full elucidation of the cellular and physiological roles of mt-AAA metalloproteases in metazoans will require the creation of targeted mutations.

The human homologue of the yeast mitochondrial AAA metalloprotease Yme1p complements a yeast yme1 disruptant.

In yeast, three AAA superfamily metalloproteases (Yme1p, Afg3p and Rca1p) are localized to the mitochondrial inner membrane where they perform roles in the assembly and turnover of the respiratory chain complexes. We have investigated the function of the proposed human orthologue of yeast Yme1p, encoded by the YME1L gene on chromosome 10p. Transfection of both HEK-293EBNA and yeast cells with a green fluorescent protein-tagged YME1L cDNA confirmed mitochondrial targeting. When expressed in a yme1 disruptant yeast strain, YME1L restored growth on glycerol at 37 degrees C. We propose that YME1L plays a phylogenetically conserved role in mitochondrial protein metabolism and could be involved in mitochondrial pathologies.

Multisite oligonucleotide-mediated mutagenesis: application to the conversion of a mitochondrial gene to universal genetic code.

Using multisite oligonucleotide-mediated mutagenesis in conjunction with a mutagenesis selection procedure and rapid screening by allele-specific oligonucleotide hybridization has allowed us to develop a reliable protocol that enables a large number of base changes to be introduced rapidly into a piece of DNA, with the minimum number of manipulations. We have applied this protocol to generate synthetic versions of four mouse mitochondrial genes capable of being expressed in the nucleus/cytosol.

Replication origins and pause sites in sea urchin mitochondrial DNA.

We have used a combination of one- and two-dimensional agarose gel electrophoresis, and solution hybridization to strand-specific probes, to map the replication origin of sea urchin mitochondrial DNA and to investigate the structure of replication intermediates. These assays are consistent with replication initiating unidirectionally from the D-loop region by D-loop expansion, as in vertebrates. A prominent site of initiation of lagging-strand synthesis lies at, or near to, the boundary between the genes for ATPase 6 and COIII, which is also close to a pause site for leading-strand synthesis. These findings suggest a role for pause sites in the regulation of mitochondrial transcription and replication, possibly involving template-binding proteins.