The cyt-20-1 mutant of Neurospora crassa is a temperature-sensitive, cytochrome b- and aa3-deficient strain that is severely deficient in both mitochondrial and cytosolic protein synthesis (R.A. Collins, H. Bertrand, R.J. LaPolla, and A.M. Lambowitz, Mol. Gen. Genet. 177:73-84, 1979). We cloned the cyt-20+ gene by complementation of the cyt-20-1 mutation and found that it contains a 1,093-amino-acid open reading frame (ORF) that encodes both the cytosolic and mitochondrial valyl-tRNA synthetases (vaIRSs). A second mutation, un-3, which is allelic with cyt-20-1, also results in temperature-sensitive growth, but not in gross deficiencies in cytochromes b and aa3 or protein synthesis. The un-3 mutant had also been reported to have pleiotropic defects in cellular transport process, resulting in resistance to amino acid analogs (M.S. Kappy and R.L. Metzenberg, J. Bacteriol. 94:1629-1637, 1967), but this resistance phenotype is separable from the temperature sensitivity in crosses and may result from a mutation in a different gene. The 1,093-amino-acid ORF encoding vaIRSs is the site of missense mutations resulting in temperature sensitivity in both cyt-20-1 and un-3 and is required for the transformation of both mutants. The opposite strand of the cyt-20 gene encodes an overlapping ORF of 532 amino acids, which may also be functional but is not required for transformation of either mutant. The cyt-20-1 mutation in the vaIRS ORF results in severe deficiencies of both mitochondrial and cytosolic vaIRS activities, whereas the un-3 mutation does not appear to result in a deficiency of these activities or of mitochondrial or cytosolic protein synthesis sufficient to account for its temperature-sensitive growth. The phenotype of the un-3 mutant raises the possibility that the vaIRS ORF has a second function in addition to protein synthesis.

Neurospora mitochondrial tyrosyl-tRNA synthetase (mt tyrRS), which is encoded by nuclear gene cyt-18, functions in splicing of group I introns in mitochondria. Here, we overproduced functional cyt-18 protein in Escherichia coli and purified it to near homogeneity. The purified protein has splicing and tyrRS activities similar to those of cyt-18 protein isolated from mitochondria and is by itself sufficient to splice the mitochondrial large rRNA intron in vitro. Structure-function relationships in the cyt-18 protein were analyzed by in vitro mutagenesis. We confirmed that a small amino-terminal domain not found in bacterial tyrRSs is required for splicing activity, but not tyrRS activity. Two linker insertion mutations, which disrupt the predicted ATP-binding site, completely inhibit tyrRS activity but leave substantial splicing activity. Finally, deletions or linker insertion mutations in the putative carboxy-terminal tRNA-binding domain inhibit both tyrRS and splicing activities, although some have differential effects on the two activities. Our results show that the normal catalytic activity of the cyt-18 protein is not required for splicing and are consistent with the hypothesis that the protein functions by binding to the precursor RNA and facilitating formation of the correct RNA structure. Regions required for splicing are distributed throughout the cyt-18 protein and overlap, but are not identical to, regions required for tyrRS activity. The finding that the putative carboxy-terminal tRNA-binding domain is required for both tyrRS and splicing activities suggests that the mechanism for binding the intron has similarities to the mechanism for binding tRNA(Tyr).

The gene encoding the Neurospora mitochondrial large rRNA contains a single group I intron of 2.3 kilobases that is not self-splicing in vitro. We showed previously that the splicing of this intron in vivo and in vitro is dependent on the Neurospora cyt-18 protein, mitochondrial tyrosyl-tRNA synthetase. In the present work, we carried out further structural analysis of the intron and constructed mutant derivatives of it in order to identify features that are either required for splicing or prevent it from self-splicing. Previous studies showed that the intron contains a large hairpin structure near the 5' splice site. By mapping RNase III cleavage sites, we identified this hairpin structure as an extended P2 stem. We construct a mini-intron of 388 nucleotides by deleting the 426-amino acid intron open reading frame, most of the 5' intron hairpin, and all of L8. This mini-intron shows the same protein-dependent splicing as the full length intron, but is still not self-splicing. Further deletions, which remove all of P2 or all or part of P4, P6, P7, or P9, inactivate splicing, suggesting that an intact group I intron core structure is required. Strengthening the P1, P10, or P9.0 pairings did not enable the mini-intron to self-splice. Our findings indicate that the inability of the mitochondrial large rRNA intron to self-splice reflects deficiency of a structure or activity required for cleavage at the 5' splice site, either in the intron core itself or in the interaction between the core and the P1 stem.

The Mauriceville and Varkud mitochondrial plasmids are closely related, closed-circular DNAs (3.6 and 3.7 kb, respectively) that have characteristics of mtDNA introns and retroid elements. Both plasmids contain a 710 amino acid open reading frame (ORF) that encodes an 81 kDa protein having reverse transcriptase activity. Here, we analyzed two mutant plasmids, V5-36 and M3-24, that have undergone relatively large deletions (approximately 0.35 and 0.5 kb, respectively). Both deletions occur downstream of the long ORF in a non-coding region of the plasmids that contains a direct repeat of 160 bp and a cluster of five PstI-palindromes, a repetitive sequence element in Neurospora mtDNA. In V5-36, the deletion end points are at the bases of two hairpin structures that are centered around PstI-palindromes and flank the deleted region. In M3-24, the deletion junction contains an extra T-residue that is not encoded in the plasmid. In both plasmids, the deletion end points do not correspond to homologous or directly repeated sequences of more than one nucleotide, whose pairing could account for the deletion junction. The characteristics of the deletion end points can be accounted for either by illegitimate recombination, possibly following double strand breaks at cruciform structures, or by interruption of reverse transcription followed by reinitiation downstream. The finding that the deletions encompass the 160 bp direct repeat and all five PstI-palindromes indicates that neither are required for propagation of the plasmids and supports the hypothesis that PstI-palindromes are selfish DNA elements that inserted into a nonessential region of the plasmid.

Neurospora mitochondrial tyrosyl-tRNA synthetase (mt TyrRS), which is encoded by nuclear gene cyt-18, functions in splicing group I introns. Analysis of intragenic partial revertants of the cyt-18-2 mutant and in vitro mutants of the cyt-18 protein expressed in E. coli showed that splicing activity of the cyt-18 protein is dependent on a small N-terminal domain that has no homolog in bacterial or yeast mt TyrRSs. This N-terminal splicing domain apparently acts together with other regions of the protein to promote splicing. Our findings support the hypothesis that idiosyncratic sequences in aminoacyl-tRNA synthetase may function in processes other than aminoacylation. Furthermore, they suggest that splicing activity of the Neurospora mt TyrRs was acquired after the divergence of Neurospora and yeast, and they demonstrate one mechanism whereby splicing factors may evolve from cellular RNA binding proteins.

Using an in vitro transcription assay, we previously identified promoters in Neurospora mtDNA at the 5' ends of the genes encoding the mitochondrial (mt) small and large rRNAs and cob pre-mRNA. Here, we identified two additional promoters in mtDNA restriction fragment EcoRI-6, 3.8 and 5.5 kilobases upstream of the 5' end of the mt small rRNA. By comparing the two new promoters with the three identified previously, we derived a modified promoter consensus sequence (AT-rich)15-27TTAG(A/T)RR(G/T)(G/C)N(A/T). The mt small rRNA in Neurospora is transcribed from at least two promoters, a major promoter at the 5' end of the small rRNA and one or both of the newly identified promoters in EcoRI-6. The latter gives a series of putative pre-rRNAs that contain 5' end extensions of various sizes. The 5' ends of a number of these RNAs map at or near hairpin structures. The [poky] mutant, which is grossly deficient in the mt small rRNA, has a 4-base pair deletion in the major promoter at the 5' end of the mt small rRNA. The residual small rRNAs in [poky] appear to be synthesized via the upstream promoter(s), but are missing 37-44 nucleotides from their 5' ends, indicating either that pre-rRNAs are processed abnormally or that abnormal 5' RNA ends are unstable. The effect of the promoter mutation in [poky] on other transcripts suggests that the mt small rRNA is cotranscribed with downstream genes encoding tRNAs, coIII and ND6. Seven nonallelic nuclear suppressors of [poky] result in increased concentrations of the mt small rRNA and pre-rRNAs, but do not restore the ability to synthesize small rRNAs having the correct 5' ends. The suppressor mutations could act by increasing transcription, processing, or stability of the mt small rRNA or its precursors. The suppressors provide a genetic approach for identifying components that affect transcription and processing of the mt small rRNA.

The Mauriceville and Varkud mitochondrial plasmids of Neurospora are closely related, closed-circular DNAs (3.6 and 3.7 kilobases, respectively) that have characteristics of mtDNA introns and retroid elements. The plasmids contain a single long open reading frame (710 amino acids), whose amino-terminal half has structural similarity to reverse transcriptases. Using antibodies against synthetic peptides and trpE fusion proteins, we detected an 81-kDa protein encoded by this open reading frame in mitochondrial preparations from the plasmid-containing strains. This 81-kDa protein cosegregates with reverse transcriptase activity in sexual crosses and comigrates with reverse transcriptase activity in sodium dodecyl sulfate-polyacrylamide gels, where it can be assayed after renaturation of the protein. In glycerol gradients under nondenaturing conditions, the reverse transcriptase activity sediments at approximately 145 kDa, close to the value expected for a dimer of the 81-kDa protein. The 81-kDa protein represents most of the 710-amino acid open reading frame, but may be missing some amino acids at the amino terminus. The regions upstream and downstream of the putative reverse transcriptase domain lack sequences characteristic of gag, protease, RNase H, or integrase domains found in other retroid elements. The plasmid-encoded 81-kDa protein seems to be a novel type of reverse transcriptase that may provide insight into the evolution of these enzymes.

Group I and group II introns catalyse their own splicing, but depend on protein factors for efficient splicing in vivo. Some of these proteins, termed maturases, are encoded by the introns themselves and may also function in intron mobility. Other proteins are encoded by host chromosomal genes and include aminoacyl-tRNA synthetases and various proteins that function in protein synthesis. The splicing factors identified thus far appear to be idiosyncratic, even in closely related organisms. We suggest that some of these protein-assisted splicing reactions evolved relatively recently, possibly reflecting the recent dispersal of the introns themselves.

The Mauriceville and Varkud mitochondrial plasmids of Neurospora spp. are closely related, closed-circular DNAs (3.6 and 3.7 kilobases, respectively) whose nucleotide sequences and genetic organization suggest relationships to mitochondrial introns and retroelements. We have characterized nine suppressive mutants of these plasmids that outcompete mitochondrial DNA and lead to impaired growth. All nine suppressive plasmids contain small insertions, corresponding to or including a mitochondrial tRNA (tRNATrp, tRNAGly, or tRNAVal) or a tRNA-like sequence. The insertions are located at the position corresponding to the 5' end of the major plasmid transcript or 24 nucleotides downstream near a cognate of the sequence at the major 5' RNA end. The structure of the suppressive plasmids suggests that the tRNAs were inserted via an RNA intermediate. The 3' end of the wild-type plasmid transcript can itself be folded into a secondary structure which has tRNA-like characteristics, similar to the tRNA-like structures at the 3' ends of plant viral RNAs. This structure may play a role in replication of the plasmids by reverse transcription. Major transcripts of the suppressive plasmids begin at the 5' end of the inserted mitochondrial tRNA sequence and are present in 25- to 100-fold-higher concentrations than are transcripts of wild-type plasmids. Mapping of 5' RNA ends within the inserted mtDNA sequences identifies a short consensus sequence (PuNPuAG) which is present at the 5' ends of a subset of mitochondrial tRNA genes. This sequence, together with sequences immediately upstream in the plasmids, forms a longer consensus sequence, which is similar to sequences at transcription initiation sites in Neurospora mitochondrial DNA. The suppressive behavior of the plasmids is likely to be directly related to the insertion of tRNAs leading to overproduction of plasmid transcripts.

The cyt-2-1 mutant of Neurospora crassa is deficient in cytochromes aa3 and c and in cytochrome c heme lyase activity (Mitchell, M.B., Mitchell, H.K., and Tissieres, A. (1953) Proc. Natl. Acad. Sci. U.S.A. 39, 606-613; Nargang, F.E., Drygas, M.E., Kwong, P.L., Nicholson, D.W., and Neupert, W. (1988) J. Biol. Chem. 263, 9388-9394). By rescue of the slow growth character of the cyt-2-1 mutant, we have cloned the cyt-2+ gene from a N. crassa genomic library using sib selection. Analysis of the DNA sequence of the cyt-2+ gene revealed an open reading frame of 346 amino acids that has homology to the yeast cytochrome c heme lyase. The open reading frame is interrupted by two short introns. Codon usage and Northern hybridization analysis suggest that the cyt-2 gene is expressed at low levels. The cyt-2-1 mutant allele was cloned from a partial cyt-2-1 gene bank using the wild-type gene as a probe. Sequence analysis of the mutant gene revealed a 2-base (CT) deletion that alters the reading frame for 21 codons before generating an early stop codon in the protein-coding sequence. It was previously suggested that the cyt-2-1 mutation inactivates one of two regulatory circuits controlling the production of cytochrome aa3. The finding that the cyt-2-1 mutation affects the coding sequence for cytochrome c heme lyase provides a direct explanation for the deficiency of cytochrome c in the mutant and suggests that the lack of cytochrome aa3 is a regulatory response to the deficiency of cytochrome c.

We have developed an in vitro transcription system for Neurospora crassa mitochondrial DNA (mtDNA) and used it to identify transcription initiation sites at the 5' ends of the genes encoding the mitochondrial small and large rRNA and cytochrome b (cob). The in vitro transcription start sites correspond to previously mapped 5' ends of major in vivo transcripts of these genes. Sequences around the three transcription initiation sites define a 15-nucleotide consensus sequence, 5'-TTAGARA(T/G)G(T/G)ARTRR-3', all or part of which appears to be an element of an N. crassa mtDNA promoter. A somewhat looser 11-nucleotide consensus sequence, 5'-TTAGARR(T/G)R(T/G)A-3', was derived by including two additional promoters identified recently. Group I extranuclear mutants, such as [poky] and [SG-3], have a 4-base-pair (bp) deletion in the consensus sequence at the 5' end of the mitochondrial small rRNA and are grossly deficient in mitochondrial small rRNA (R. A. Akins and A. M. Lambowitz, Proc. Natl. Acad. Sci. USA 81:3791-3795, 1984). We show here that the 4-bp deletion in the consensus sequence decreases in vitro transcription from this site by more than 99%. N. crassa mtDNA is similar to Saccharomyces cerevisiae mtDNA in having multiple promoters, including separate promoters for the genes encoding the mitochondrial small and large rRNAs. Our results suggest that the primary effect of the 4-bp deletion in group I extranuclear mutants is to inhibit transcription of the mitochondrial small rRNA, leading to severe deficiency of mitochondrial small rRNA and small ribosomal subunits.

The temperature-sensitive Neurospora nuclear mutant cyt18-1 is deficient in splicing many Group I mitochondrial introns when grown at its non-permissive temperature; however, splicing of intron 1 in the coI gene of the Adiopodoume (formerly called North Africa) strain is unaffected (R.A. Collins and A.M. Lambowitz, J. Mol. Biol. 184: 413-428, 1985). Here we show that coI intron 1 is a typical Group II intron, the only one identified to date in Neurospora. The differential effect of the cyt18-1 mutation suggests that splicing of certain introns could be regulated independently of others by nuclear-encoded proteins. The intron contains a long open reading frame (ORF) resembling that of the Neurospora Mauriceville mitochondrial plasmid. The intron and plasmid ORFs share unusual features of codon usage that suggest both evolved outside of the Neurospora mitochondrial genetic system.

Neurospora crassa mitochondria use a branched electron transport system in which one branch is a conventional cytochrome system and the other is an alternative cyanide-resistant, hydroxamic acid-sensitive oxidase that is induced when the cytochrome system is impaired. We used a monoclonal antibody to the alternative oxidase of the higher plant Sauromatum guttatum to identify a similar set of related polypeptides (Mr, 36,500 and 37,000) that was associated with the alternative oxidase activity of N. crassa mitochondria. These polypeptides were not present constitutively in the mitochondria of a wild-type N. crassa strain, but were produced in high amounts under conditions that induced alternative oxidase activity. Under the same conditions, mutants in the aod-1 gene, with one exception, produced apparently inactive alternative oxidase polypeptides, whereas mutants in the aod-2 gene failed to produce these polypeptides. The latter findings support the hypothesis that aod-1 is a structural gene for the alternative oxidase and that the aod-2 gene encodes a component that is required for induction of alternative oxidase activity. Finally, our results indicate that the alternative oxidase is highly conserved, even between plant and fungal species.

We reported previously that mitochondrial tyrosyl-tRNA synthetase, which is encoded by the nuclear gene cyt-18 in Neurospora crassa, functions in splicing several group I introns in N. crassa mitochondria (R. A. Akins and A. M. Lambowitz, Cell 50:331-345, 1987). Two mutants in the cyt-18 gene (cyt-18-1 and cyt-18-2) are defective in both mitochondrial protein synthesis and splicing, and an activity that splices the mitochondrial large rRNA intron copurifies with a component of mitochondrial tyrosyl-tRNA synthetase. Here, we used antibodies against different trpE-cyt-18 fusion proteins to identify the cyt-18 gene product as a basic protein having an apparent molecular mass of 67 kilodaltons (kDa). Both the cyt-18-1 and cyt-18-2 mutants contain relatively high amounts of inactive cyt-18 protein detected immunochemically. Biochemical experiments show that the 67-kDa cyt-18 protein copurifies with splicing and synthetase activity through a number of different column chromatographic procedures. Some fractions having splicing activity contain only one or two prominent polypeptide bands, and the cyt-18 protein is among the few, if not only, major bands in common between the different fractions that have splicing activity. Phosphocellulose columns resolve three different forms or complexes of the cyt-18 protein that have splicing or synthetase activity or both. Gel filtration experiments show that splicing activity has a relatively small molecular mass (peak at 150 kDa with activity trailing to lower molecular masses) and could correspond simply to dimers or monomers, or both, of the cyt-18 protein. Finally, antibodies against different segments of the cyt-18 protein inhibit splicing of the large rRNA intron in vitro. Our results indicate that both splicing and tyrosyl-tRNA synthetase activity are associated with the same 67-kDa protein encoded by the cyt-18 gene. This protein is a key constituent of splicing activity; it functions directly in splicing, and few, if any, additional components are required for splicing the large rRNA intron.

The nuclear cyt-4 mutants of Neurospora crassa have been shown previously to be defective in splicing the group I intron in the mitochondrial large rRNA gene and in 3' end synthesis of the mitochondrial large rRNA. Here, Northern hybridization experiments show that the cyt-4-1 mutant has alterations in a number of mitochondrial RNA processing pathways, including those for cob, coI, coII and ATPase 6 mRNAs, as well as mitochondrial tRNAs. Defects in these pathways include inhibition of 5' and 3' end processing, accumulation of aberrant RNA species, and inhibition of splicing of both group I introns in the cob gene. The various defects in mitochondrial RNA synthesis in the cyt-4-1 mutant cannot be accounted for by deficiency of mitochondrial protein synthesis or energy metabolism, and they suggest that the cyt-4-1 mutant is defective in a component or components required for processing and/or turnover of a number of different mitochondrial RNAs. Defective splicing of the mitochondrial large rRNA intron in the cyt-4-1 mutant may be a secondary effect of failure to synthesize pre-rRNAs having the correct 3' end. However, a similar explanation cannot be invoked to account for defective splicing of the cob pre-mRNA introns, and the cyt-4-1 mutation may directly affect splicing of these introns.

We showed previously that the cyt-21+ gene of Neurospora crassa encodes a mitochondrial ribosomal protein homologous to Escherichia coli ribosomal protein S-16 (Kuiper, M. T. R., Akins, R. A., Holtrop, M., de Vries, H., and Lambowitz, A. M. (1988) J. Biol. Chem. 263, 2840-2847). A mutation in this gene, cyt-21-1, results in deficiency of mitochondrial small ribosomal subunits and small rRNA (Collins, R. A., Bertrand, H., LaPolla, R. J., and Lambowitz, A. M. (1979) Mol. Gen. Genet. 177, 73-84). In the present work, cloning and sequencing of the cyt-21-1 mutant allele show that it contains a single dG to dA transition at the 3' splice site AG of the first intron in the protein coding region. This mutation leads to inactivation of the normal 3' splice site and activation of a cryptic 3' splice site, 15 nucleotides downstream. The use of this cryptic splice site results in an in-frame deletion of 5 amino acids from the cyt-21 protein. Comparison of mutant and wild-type mitochondrial small ribosomal subunit proteins showed one protein, S-24, with an altered electrophoretic mobility, consistent with the predicted deletion. The mutant ribosomal protein is still capable of binding to mitochondrial small ribosomal subunits, but results in abnormal mitochondrial ribosome assembly.

The Neurospora crassa nuclear mutant cyt-21-1 (originally 297-24; Pittenger, T.H., and West, D.J. (1979) Genetics 93, 539-555) has a defect leading to gross deficiency of mitochondrial small ribosomal subunits. Here, we have cloned the cyt-21+ gene from a N. crassa genomic library, using the sib selection procedure (Akins, R. A., and Lambowitz, A. M. (1985) Mol. Cell Biol. 5, 2272-2278). The genomic clone contains a short split gene encoding a basic protein of 107 amino acid residues. This protein shows strong homology to Escherichia coli ribosomal protein S-16. Comparison of mutant and wild-type mitochondrial ribosomal proteins (Kuiper, M. T. R., Holtrop, M., Vennema, H., Lambowitz, A. M., and de Vries, H. (1988) J. Biol. Chem. 263, 2848-2852) indicates that the cyt-21 gene encodes N. crassa mitochondrial ribosomal protein S-24. The expression of the cyt-21+ gene is regulated such that the level of the putative cyt-21+ mRNA is increased about 5-fold when mitochondrial protein synthesis is inhibited. We suggest that this reflects part of a general mechanism for coordinately activating Neurospora nuclear genes that encode mitochondrial constituents in response to impaired mitochondrial function. This is the first report of the cloning and characterization of a mitochondrial ribosomal protein gene from N. crassa.

van+, a gene encoding a phosphorus-repressible phosphate permease, was isolated by its ability to complement nuc-1, a positive regulatory locus that normally regulates van+ expression. This was unexpected because the nuc-1 host already contained a resident van+ gene. Plasmids carrying van+ complemented a nuc-2 mutation as well. Probing of RNA from untransformed wild-type (nuc-1+) and constitutive (nuc-1c) strains by van+ probes indicated that levels of the van+ transcript were subject to control by nuc-1+. Probing of the same RNAs with a cosmid clone, containing approximately 15 kilobases of upstream and downstream DNA, revealed no other detectable phosphorus-regulated transcripts within this 40-kilobase region of the chromosome.

The Mauriceville and Varkud mitochondrial plasmids of Neurospora are closely related DNA elements whose nucleotide sequences and genetic organization suggest relationships to retrotransposons and mitochondrial introns. Both plasmids potentially encode a reverse transcriptase-like protein of 710 amino acids. We show that mitochondria from the Mauriceville and Varkud strains contain a reverse transcriptase activity highly specific for endogeneous plasmid RNA in RNP preparations. The reverse transcriptase synthesizes full-length minus-strand DNA beginning at the 3' end of the plasmid transcript, which has tRNA-like characteristics similar to the 3' ends of plant viral RNAs. Our results suggest that the plasmids use a novel mechanism of reverse transcription, which may have evolved to utilize tRNA-like structures at the 3' ends of self-replicating RNAs. This mechanism may be ancestral to the standard retroviral mechanism.