Transcription of Tetrahymena mitochondrial DNA in vivo

Unexpectedly long 14S ribosomal RNA gene in Tetrahymena mitochondria

Extraction of RNA from Tetrahymena mitochondrial ribosomes yields several RNA species, including a "large" 21S molecule, a "small" 14S molecule, a 7S molecule, and other smaller RNAs. The molecular weight of the 14S rRNA indicates that it is about 1,300 bases in length. We have sequenced the 14S rRNA gene and, by aligning our sequence with that of the corresponding small rRNA from E. coli, find that the 14S rDNA is at least 1,635 bases in length. We propose, based on the results of hybridization studies, that this unexpected length is due to the presence of 7S RNA sequence within the 14S gene sequence. The 7S region is apparently lost from the 14S rRNA, yet is still a component of the ribosome.

Two dimensional polyacrylamide gel electrophoresis analysis of Tetrahymena mitochondrial tRNA

Two dimensional (2D) urea-polyacrylamide gel electrophoresis of tRNA isolated from Tetrahymena mitochondria separated at least 36 spots, while more than 45 major and minor spots were resolved with cytosolic tRNA. Co-electrophoresis of mitochondrial and cytosolic tRNAs revealed that many spots co-migrate. When radioactive mitochondrial tRNA was hybridized to mtDNA under various conditions and tRNA melted from the hybrid was analyzed by 2D gel electrophoresis, only 10 tRNA spots were found. Identified as mtDNA-encoded were 2 spots for tRNA(leu), 2 for tRNA(met), and 1 each for tRNA(phe), tRNA(trp) and tRNA(tyr). The remaining three were unidentified. Mitochondrial tRNA spots that correspond to the tRNAs for arg, gly, ile, lys, ser, and val do not hybridize with mtDNA, and in gel positions they correspond to the cytoplasmic tRNA spots for the same respective amino acids. These mitochondrial tRNAs isolated from the gel can be acylated either by the mitochondrial or cytosolic enzymes. Mitochondrial tRNA isolated from a Tetrahymena cell homogenate which was pretreated with RNase A and Micrococcus nuclease exhibited the same 2D gel pattern as a non-treated control. Mitochondrial tRNAs from old and young cells showed generally similar tRNA spots in 2D gels, though more variable spots were seen with old cells. 3H-labeled whole-cell tRNA added to the cell homogenate prior to the mitochondrial isolation procedure did not remain associated with the final mitochondrial tRNA preparation. The present studies also showed mitochondrial tRNAs bound to the mitochondrial 80S monosome and polysome fractions. Radioactive tRNA added to the mitochondrial lysate does not adhere to the ribosomes, suggesting that the ribosome-bound tRNAs are not contaminating cytoplasmic tRNAs. These results are generally in good agreement with our previous data showing that only a small number of tRNAs are coded for by the mitochondrial DNA, while the others are a selected set of imported cytoplasmic tRNAs.

A fine restriction map of the linear mitochondrial DNA of Tetrahymena pyriformis: genome size, map locations of rRNA and tRNA genes, terminal inversion repeat, and restriction site polymorphism

A fine restriction map of the linear mitochondrial DNA of Tetrahymena pyriformis strain ST is presented. 1. Based on agarose gel electrophoresis data together with limited nucleotide sequences available on some restriction fragments, we estimate the actual size of this genome to be about 55,000 base pairs. 2. Seven tRNA gene locations have been assigned, which are scattered along the genome length. Six of these locations encode the genes for tRNA(phe), tRNA(his), tRNA(trp), and tRNA(glu), and the duplicate tRNA(tyr) genes which are located at the inverted terminal repeat segments. The tRNA gene(s) encoded in one location has not been identified. We have not yet found the tRNA(leu) and tRNA(met) genes, which were previously shown to be encoded in the genome (Chiu et al. 1974; Suyama 1982). 3. We have mapped the 14S rRNA gene by sequencing the 170 bp segment of EcoRI fragment 8 and by aligning its sequence with E. coli 16S rRNA. From our recent complete sequence data the gene size was found to be about 1,650 bp, which is unexpectedly large for the 14S rRNA which has an estimated size of 1,300 bp. The 14S rRNA is probably a cleavage product of the larger primary transcript of which 200-300 bases of the 5' end are missing. 4. The duplicate copies of the 21S rRNA gene at the terminal duplication inversion segments were analyzed. ClaI fragment 7 (1,500 bp) corresponds in sequence from base position 850 to 2,390 of the 20S rRNA gene of Paramecium mitochondrial DNA (Seilhamer et al. 1984b). The 21S gene is approximately 2,500 bp long. The presence of some restriction site polymorphism is apparent in this segment. 5. Each of the 21S gene copies precedes the tRNA(tyr) gene, but the space flanking one tRNA(tyr) gene differs in size and restriction sites from the space flanking another tRNA(tyr) gene. Thus, this space corresponds to the segment of an imperfect match in the terminal duplication inversion of Goldbach et al. (1978a). 6. Saccharomyces cerevisiae mitochondrial probes including Cob, ATPase VI and IX, and cytochrome oxidase I gene sequences, 21S and 15S rRNAs, and mouse mitochondrial DNA showed no significant hybridization with any restriction fragments of Tetrahymena mitochondrial DNA. The results are in accordance with an extensive sequence divergence previously found in the Tetrahymena mitochondrial genome (Goldbach et al. 1977).

Uniqueness of sperm mtDNA as compared to somatic mtDNA in ram

Sperm mtDNA exhibits unique physicochemical properties compared with mtDNA from somatic tissues in the ram. The buoyant density of sperm mtDNA was 1,6983 g/cm3 while the brain, heart and liver mtDNAs was about 1.7005 g/cm3. The Tm of the liver and sperm mtDNA was 71.0 degrees C and 69.5 degrees C, respectively. The G + C content of sperm mtDNA was 3.0 moles % lower than the liver mtDNA. The contour length of the circular sperm mtDNA was 5.01 micrometers compared with the liver mtDNA with contour length of 5.33 micrometers.

Conservation of the sequence and position of the ribosomal RNA genes in Tetrahymena pyriformis mitochondrial DNA

1. We have done cross-hybridizations between the mitochondrial ribosomal RNAs and DNAs from strains ST and PP of Tetrahymena pyriformis. DNA . ribosomal RNA hybrid formation can be completely prevented by an excess of the heterologous ribosomal RNA and the heterologous hybrids melt 6 degrees C below the homologous hybrids. This shows that the ribosomal RNA cistrons can account for the 5% cross-hybridization previously observed between the mtDNAs of strains PP and ST (Goldbach et al. (1977) Biochim. Biophys. Acta 477, 37--50). 2. By electron microscopy of DNA . ribosomal RNA hybrids we have determined the position of the ribosomal RNA cistrons on the mtDNA of strain GL, a mtDNA which we have shown to contain a sub-terminal 1 micron duplication-inversion and a terminal palindrome at one end which varies in length from 0 to 5 micron and which includes the 1 micron duplication-inversion (Arnberg et al. (1977) Biochim. Biophys. Acta 477, 51--69). The 21 S ribosomal RNA cistron overlaps the 1 micron duplication-inversion and as a result two or three cistrons are present, depending on the size of the terminal palindrome. Only one 14 S ribosomal RNA cistron is found, located about 10 000 base pairs away from the nearest 21 S cistron is found, located about 10 000 base pairs away from the nearest 21 S cistron and with the same polarity as this cistron. 3. We conclude from these results and those in the preceding paper that the sequence of the ribosomal RNAs and the position of the ribosomal RNA genes in the mtDNA is strongly conserved in Tetrahymena. Possible reasons for the duplication of 21-S ribosomal RNA genes and the terminal heterogeneity of Tetrahymena mtDNA are discussed.

The organization of ribosomal RNA genes in the mitochondrial DNA of Tetrahymena pyriformis strain ST

1. We have constructed a physical map of the mtDNA of Tetrahymena pyriformis strain ST using the restriction endonucleases EcoRI, PstI, SacI, HindIII and HhaI. 2. Hybridization of mitochondrial 21 S and 14 S ribosomal RNA to restriction fragments of strain ST mtDNA shows that this DNA contains two 21-S and only one 14-S ribosomal RNA genes. By S1 nuclease treatment of briefly renatured single-stranded DNA the terminal duplication-inversion previously detected in this DNA (Arnberg et al. (1975) Biochim. Biophys. Acta 383, 359--369) has been isolated and shown to contain both 21-S ribosomal RNA genes. 14 S ribosomal RNA hybridizes to a region in the central part of the DNA, about 8000 nucleotides or 20% of the total DNA length apart from the nearest 21 S ribosomal RNA gene. 3. We have confirmed this position of the three ribosomal RNA genes by electron microscopical analysis of DNA . RNA hybrid molecules and R-loop molecules. 4. Hybridization of 21 S ribosomal RNA with duplex mtDNA digested either with phage lambda-induced exonuclease or exonuclease III of Escherichia coli, shows that the 21-S ribosomal RNA genes are located on the 5'-ends of each DNA strand. Electron microscopy of denaturated mtDNA hybridized with a mixture of 14-S and 21-S ribosomal RNAs show that the 14 S ribosomal RNA gene has the same polarity as the nearest 21 S ribosomal RNA gene. 5. Tetrahymena mtDNA is (after Saccharomyces mtDNA) the second mtDNA in which the two ribosomal RNA cistrons are far apart and the first mtDNA in which one of the ribosomal RNA cistrons is duplicated.

The structure of Tetrahymena pyriformis mitochondrial DNA. I. Strain differences and occurrence of inverted repetitions

We have analysed the structure of the mtDNAs of six amicronucleate Tetrahymena pyriformis strains, belonging to at least four phenosets, as defined by Borden et al. (Borden, D., Whitt, G.S. and Nanney, D.L. (1973) J. Protozool. 20, 693--700). 2. The mtDNAs of all strains are linear, but they differ in size, in their fragmentation by endonuclease EcoRI and in overall sequence; less than 20% sequence homology was found by DNA-DNA hybridization in all combinations tested, except for the mtDNAs from strains T and ST which are indistinguishable. 3. In spite of these marked sequence differences the mtDNAs of all strains share two structural peculiarities: ragged (gnawed) duplex ends and a duplication-inversion, which varies in length between 0.3 and 1.2 micrometer, depending on the strain. In four strains the duplication-inversion is terminal, allowing formation of single-stranded DNA circles with a duplex tail; in two strains it is subterminal. 4. The ragged ends and sub-terminal position of the duplication-inversion in some of the Tetrahymena mtDNAs do not fit any of the current models for the replication of linear mtDNAs.

The binding of poly(rA) and poly(rU) to denatured DNA. I. Model studies with homopolymers

We have compared the properties of the poly(rA).oligo(dT) complex with those of the poly(rU).oligo(dA)n complex. Three main differences were found. First, poly(rA) and oligo(dT)n do not form a complex in concentrations of CsCl exceeding 2 M because the poly(rA) is insoluble in high salt. If the complex is made in low salt, it is destabilized if the CsCl concentration is raised. Complexes between poly(rU) and oligo(dA)n, on the other hand, can be formed in CsCl concentrations up to 6.6 M. Second, complexes between poly(rA) and oligo(dT)n are more rapidly destabilized with decreasing chain length than complexes between poly(rU) and oligo(dA)n. Third, the density of the complex between poly(rA) and poly(dT) in CsCl is slightly lower than that of poly(dT), whereas the density of the complex between poly(rU) and poly(dA) in CsCl is at least 300 g/cm3 higher than that of poly(dA). These results explain why denatured natural DNAs that bind poly(rU) in a CsCl gradient usually do not bind poly(rA).

The origin of mitochondria

The endosymbiont and episome theories about the origin of mitochondria are reviewed. Biochemical and genetic data, relevant to these theories are discussed. An alternative theory is also proposed; this theory is that nuclear and mitochondrial DNAs developed from compartmentalized duplicate prokaryote DNAs.

Synthesis of mitochondrial proteins in an Escherichia coli cell-free system directed by yeast mitochondrial DNA

The optimum conditions for transcription in vitro of yeast mtDNA into biologically relevant RNA by Escherichia coli RNA polymerase holoenzyme and yeast mitochondrial RNA polymerase was found to critically depend on salt concentration. RNA was transcribed (at 0.25 M KCl concentration) from high-molecular-weight mtDNA which was then translated in an E. coli (S-30) cell-free protein synthesising system. Efficient translation of mitochondrial RNA was achieved using conditions which had also been determined to be optimal in other systems. Identification of the polypeptides produced in the translation system was made using antiserum raised against mitochondrial membranes. Electrophoresis of the completely dissociated antigen-antibody complexes using dodecylsulphate-polyacrylamide gels revealed that the system in vitro produced polypeptides of similar molecular weight to those synthesised in vivo by cycloheximide-inhibited whole cells.

Mitochondrial DNA of Tetrahymena pyriformis strain ST contains a long terminal duplication-inversion

1. We have studied denatured Tetrahymena mtDNA by electron microscopy using the formamide technique. 2. After denaturation all DNA is single stranded, but within a few minutes single-stranded circles with a duplex tail are formed. 3. The duplex tail is 1.3 mum long, i.e. 8 percent of the length of native mtDNA, and it often contains a small single-stranded eye. 4. Digestion of the duplex DNA with exonuclease III of Escherichia coli abolishes its ability to form circles and duplex tails after denaturation. 5. Renaturation of denatured mtDNA leads to the formation of duplex circles with single-stranded section and/or duplex tails. In addition, a minority of duplex circles without apparent tails is formed, but these circles contain a small ambiguous section. 6. We conclude that this mtDNA contains a long terminal duplication-inversion, that could be involved in the replication of this linear mtDNA.

Mitochondrial and cytoplasmic ribosomes from Tetrahymena pyriformis. Correlative analysis by gel electrophoresis and electron microscopy

Mitochondrial and cytoplasmic ribosomes from Tetrahymena pyriformis have been isolated and studied by the techniques of polyacrylamide gel electrophoresis and electron microscopy used in conjunction. Although the two ribosome types show the same coefficient of sedimentation (80S) in sucrose gradients, they can be distinguished by gel electrophoresis: mitoribosomes migrate in a single band, considerably slower than the cytoribosome band. Electron microscope observations of negatively stained cytoribosomes show typical rounded or triangular profiles, about 275 x 230 A; mitoribosome profiles are much larger and clearly elongate, about 370 x 240 A. An electron-opaque spot delimits two nearly equal size subunits. In mixtures of mito- and cytoribosomes, each type can be recognized by its characteristic electrophoretic mobility and by its distinctive fine structure. Cytoribosomal 60S and 40S subunits each produce a distinct electrophoretic band. On the contrary, neither electrophoretic analysis, using a variety of conditions, nor electron microscopy is able to discern two different subunit types in the single 55S mitoribosomal subunit peak. Electrophoretic analysis of RNA shows that both ribosomal RNA species are present in the mitoribosomal subunit fraction. These results establish that mitoribosomes from T. pyriformis dissociate into two subunits endowed with the same sedimentation coefficient, the same electrophoretic mobility, and a similar morphology.