Nuclear gene for mitochondrial leucyl-tRNA synthetase of Neurospora crassa: isolation, sequence, chromosomal mapping, and evidence that the leu-5 locus specifies structural information.

We have isolated and characterized the nuclear gene for the mitochondrial leucyl-tRNA synthetase (LeuRS) of Neurospora crassa and have established that a defect in this structural gene is responsible for the leu-5 phenotype. We have purified mitochondrial LeuRS protein, determined its N-terminal sequence, and used this sequence information to identify and isolate a full-length genomic DNA clone. The 3.7-kilobase-pair region representing the structural gene and flanking regions has been sequenced. The 5' ends of the mRNA were mapped by S1 nuclease protection, and the 3' ends were determined from the sequence of cDNA clones. The gene contains a single short intron, 60 base pairs long. The methionine-initiated open reading frame specifies a 52-amino-acid mitochondrial targeting sequence followed by a 942-amino-acid protein. Restriction fragment length polymorphism analyses mapped the mitochondrial LeuRS structural gene to linkage group V, exactly where the leu-5 mutation had been mapped before. We show that the leu-5 strain has a defect in the structural gene for mitochondrial LeuRS by restoring growth under restrictive conditions for this strain after transformation with a wild-type copy of the mitochondrial LeuRS gene. We have cloned the mutant allele present in the leu-5 strain and identified the defect as being due to a Thr-to-Pro change in mitochondrial LeuRS. Finally, we have used immunoblotting to show that despite the apparent lack of mitochondrial LeuRS activity in leu-5 extracts, the leu-5 strain contains levels of mitochondrial LeuRS protein to similar to those of the wild-type strain.     

Cytoplasmic Leucyl-Trna Synthetase of Neurospora Crassa Is Not Specified by the Leu-5 Locus

We generated a lambda gt11 Neurospora crassa cDNA library and screened the library for the cytoplasmic leucyl-tRNA synthetase (cyto LeuRS) clones using cyto LeuRS specific antibody. Two clones, lambda NCLRSC1 and lambda NCLRSC2, were obtained which have inserts of approximately 2 kbp and approximately 1.3 kbp, and which overlap by about 0.6 kbp. The following lines of evidence indicate that lambda NCLRSC1 and lambda NCLRSC2 encode parts of cyto LeuRS. (1) Antibodies affinity purified using either of the fusion proteins encoded by lambda NCLRSC1 or lambda NCLRSC2 inhibit cyto LeuRS activity. Thus, the fusion protein and cyto LeuRS share immunological determinants. (2) The same antibodies also react with an approximately 115-kDa protein, which comigrates with purified cyto LeuRS, in immunoblots of total N. crassa proteins. We used the cDNA clones to probe a N. crassa genomic DNA library and isolated two genomic DNA clones. Partial sequence analysis of cDNA and genomic DNA clones shows a methionine initiated open reading frame, which includes a stretch of amino acid residues that are highly conserved and that are at the ATP binding site in aminoacyl-tRNA synthetases. Using the cloned DNA as probe, we show that the cyto LeuRS mRNA is approximately 3900 nucleotides long. Finally, we have used restriction fragment length polymorphism mapping to show that the cyto LeuRS gene resides on the far right of linkage group II and not on linkage group V where the leu-5 mutation, which was previously reported to specify cyto LeuRS, is located.     

Mitochondrial gene URFN of Neurospora crassa codes for a long polypeptide with highly repetitive structure

The mitochondrial DNA of Neurospora crassa contains a long potential gene, designated URFN, which is located immediately downstream from the CO1 gene. These two genes are encoded in different reading frames and overlap by 13 codons. URFN is 633 triplets long and terminates at a UAG stop codon. Its codon usage is atypical for N. crassa mitochondrial exons and introns, and resembles that of the long open reading frame (ORF) of the mitochondrial plasmid present in N. crassa strain Mauriceville. Multiple sequence repetitions occur in the presumptive URFN polypeptide, most notably a seven-times reiterated motif of 16 to 18 amino acid residues length. The hydropathy pattern shows that the N-terminal third of the URFN polypeptide is predominantly apolar and includes several potentially membrane-spanning stretches; the remaining part is hydrophilic. Calculation of the secondary structure predicts a high proportion (47%) of alpha-helix conformation. The longest alpha-helix contains 40 residues. No similarities to other mitochondrial genes or reading frames have been found, except a significant homology over a stretch of 16 amino acid residues between the N-terminal part of URFN and a well-conserved sequence in the C-terminal region of CO1. The repetitive region in URFN resembles a similarly repetitive stretch in an unassigned reading frame from bacteriophage lambda. Three arguments support the view that URFN is translated. The open reading frame has a considerable length; URFN is transcribed into a mRNA including the overlapping CO1 gene; URFN is most probably conserved among all the various Neurospora species examined thus far, strongly suggesting that it codes for an essential protein.     

Cytochrome oxidase subunit V gene of Neurospora crassa: DNA sequences, chromosomal mapping, and evidence that the cya-4 locus specifies the structural gene for subunit V.

The sequences of cDNA and genomic DNA clones for Neurospora cytochrome oxidase subunit V show that the protein is synthesized as a 171-amino-acid precursor containing a 27-amino-acid N-terminal extension. The subunit V protein sequence is 34% identical to that of Saccharomyces cerevisiae subunit V; these proteins, as well as the corresponding bovine subunit, subunit IV, contain a single hydrophobic domain which most likely spans the inner mitochondrial membrane. The Neurospora crassa subunit V gene (cox5) contains two introns, 398 and 68 nucleotides long, which share the conserved intron boundaries 5'GTRNGT...CAG3' and the internal consensus sequence ACTRACA. Two short sequences, YGCCAG and YCCGTTY, are repeated four times each in the cox5 gene upstream of the mRNA 5' termini. The cox5 mRNA 5' ends are heterogeneous, with the major mRNA 5' end located 144 to 147 nucleotides upstream from the translational start site. The mRNA contains a 3'-untranslated region of 186 to 187 nucleotides. Using restriction-fragment-length polymorphism, we mapped the cox5 gene to linkage group IIR, close to the arg-5 locus. Since one of the mutations causing cytochrome oxidase deficiency in N. crassa, cya-4-23, also maps there, we transformed the cya-4-23 strain with the wild-type cox5 gene. In contrast to cya-4-23 cells, which grow slowly, cox5 transformants grew quickly, contained cytochrome oxidase, and had 8- to 11-fold-higher levels of subunit V in their mitochondria. These data suggest (i) that the cya-4 locus in N. crassa specifies structural information for cytochrome oxidase subunit V and (ii) that, in N. crassa, as in S. cerevisiae, deficiencies in the production of nuclearly encoded cytochrome oxidase subunits result in deficiency in cytochrome oxidase activity. Finally, we show that the lower levels of subunit V in cya-4-23 cells are most likely due to substantially reduced levels of translatable subunit V mRNA.     

Cyclosporin A-binding protein (cyclophilin) of Neurospora crassa. One gene codes for both the cytosolic and mitochondrial forms

Cyclophilin (cyclosporin A-binding protein) has a dual localization in the mitochondria and in the cytosol of Neurospora crassa. The two forms are encoded by a single gene which is transcribed into mRNAs having different lengths and 5' termini (approximately 1 and 0.8 kilobases). The shorter mRNA specifies the cytosolic protein consisting of 179 amino acids. The longer mRNA is translated into a precursor polypeptide with an amino-terminal extension of 44 amino acids which is cleaved in two steps upon entry into the mitochondrial matrix. Neurospora cyclophilin shows about 60% sequence homology to human and bovine cyclophilins.     

Nucleotide sequence and evolution of the rat mitochondrial cytochrome b gene containing the ochre termination codon

The nucleotide sequences of the genes for cytochrome b and three potential transfer RNAs (tRNAPro, tRNAThr and tRNAGlu) in cloned rat mitochondrial DNA were determined. The derived amino acid sequence of the cytochrome b protein from the light strand indicated that the C-terminal amino acid is asparagine and the ochre termination codon is encoded in the DNA, in contrast to the the lack of termination codon in the reading frame of human [Anderson et al., Nature 290 (1981) 457] or mouse [Bibb et al., Cell 26 (1981) 167] mitochondrial DNA. The first ATG codon of the cytochrome b gene was spaced five nucleotides from the 5'-end of the tRNAGlu gene on the heavy strand. There was a single nucleotide spacing between the termination codon of the cytochrome b gene and the 5' end of the tRNAThr gene in the light strand. There was also a single nucleotide spacing between the 3'-end of the tRNAThr gene and the 3'-end of the tRNAPro gene on the heavy strand. The amino acid and nucleotide sequences of the cytochrome b genes of mammals and yeast [Nobrega and Tzagoloff, J. Biol. Chem. 255 (1980) 9828] were compared to reveal structural differences in two very different species. At the same time, amino acid substitutions in particular regions of the mammalian gene corresponding to the exon-intron boundaries in the yeast gene were noted. These genetic features are discussed in relation to the extreme compression of genetic information in the mammalian mitochondrial genome as related to the evolution of the gene organization and its sequence.     

The Candida albicans gene encoding the cytoplasmic leucyl-tRNA synthetase: implications for the evolution of CUG codon reassignment

In a number of Candida species the 'universal' leucine codon CUG is decoded as serine. To help understand the evolution of such a codon reassignment we have analyzed the Candida albicans leucyl-tRNA synthetase (CaLeuRS) gene (CaCDC60). The predicted CaLeuRS sequence shows a significant level of amino acid identity to LeuRS from other organisms. A mitochondrial LeuRS (ScNAM2) homologue, which shared low identity with the CaLeuRS, was also identified in C. albicans. Antigenically-related LeuRSs were identified in a range of Candida species decoding the CUG codon as both serine and leucine, using an antibody raised against the N-terminal 15 amino acids of the CaLeuRS. Complementation experiments demonstrated that the CaLeuRS was able to functionally complement a Saccharomyces cerevisiae cdc60::kanMX null mutation. We conclude that there is no alteration in tRNA recognition and aminoacylation by the C. albicans LeuRS, which argues against it having a role in codon reassignment. The nucleotide sequences of the CaCDC60 and CaNAM2 genes were deposited at GenBank under Accession numbers AF293346 and AF352020, respectively.     

Cloning and characterization of the DAS gene encoding the major methanol assimilatory enzyme from the methylotrophic yeast Hansenula polymorpha.

A gene library from the methanol utilizing yeast Hansenula polymorpha, constructed in a lambda Charon4A vector, was used to clone the gene encoding a key methanol assimilating enzyme, dihydroxyacetone synthase (DHAS) by differential plaque hybridization. The nucleotide sequence of the 2106 bp structural gene and the 5' and 3' non-coding regions was determined. The deduced amino acid sequence of the protein is in agreement with the apparent molecular weight and amino acid composition of the purified protein. The codon bias is not so pronounced as in some Saccharomyces cerevisiae genes.     

Molecular comparison of the negative-acting nitrogen control gene,nmr, inNeurospora crassa and otherNeurospora and fungal species

In Neurospora crassa, the expression of unlinked structural genes which encode nitrogen catabolic enzymes is subject to genetic and metabolic regulation. The negative-acting nmr regulatory gene appears to play a role in nitrogen catabolite repression. Using the N. crassa nmr gene as a probe, homologous sequences were identified in a variety of other filamentous fungi. The polymerase chain reaction was used to isolate the nmr-like gene from the exotic Mauriceville strain of N. crassa and from the two related species, N. intermedia and N. sitophila. Sequence comparisons were carried out with a 1.7-kb DNA segment which includes the entire coding region of nmr plus 5' and 3' noncoding sequences. The size of the nmr coding region was identical in all three Neurospora species. Approximately 30 nucleotide base substitutions were found in the coding region of the nmr gene of each of the sister species when compared to the standard N. crassa sequence. However, most of the base changes occurred in third codon positions and were silent. The NMR proteins of N. sitophila and of N. intermedia display only three and four amino acid substitutions, respectively, from the N. crassa protein. Two regions of high variability, which include deletions and insertions of bases, were found in the 5' and 3' noncoding regions of the gene.     

Cytochrome oxidase subunit III gene in Neurospora crassa mitochondria. Location and sequence

We have located and sequenced the gene for cytochrome oxidase subunit III (CoIII) in Neurospora crassa mitochondria. The CoIII gene is located downstream from the small rRNA gene within a cluster of tRNA genes and is coded by the same strand as the tRNA and the rRNA genes. Like the tRNA and the rRNA genes, the CoIII gene is also flanked by the GC-rich palindromic DNA sequences which are highly conserved in N. crassa mitochondria. The CoIII coding sequence predicts a protein 269 amino acids long including 8 tryptophan residues. All 8 tryptophan residues are coded for by UGA. This supports our previous conclusion based on the anticodon sequence of N. crassa mitochondrial tryptophan tRNA and provides evidence for the notion that use of UGA as a codon for tryptophan rather than chain termination may be a feature common to most mitochondrial protein synthesis systems. The close correspondence between the amino acid composition of N. crassa CoIII and that of the protein predicted by the CoIII gene sequence suggests that unlike in mammalian mitochondria, AUA is a codon for isoleucine and not for methionine in N. crassa mitochondria. The N. crassa CoIII sequence shows strong homologies to the corresponding yeast and human proteins (53 and 47%, respectively). The overall hydrophobic character of the protein is consistent with suggestions that most of CoIII is embedded in the mitochondrial inner membrane.     

Isolation and characterization of a Neurospora crassa ribosomal protein gene homologous to CYH2 of yeast.

We have isolated and characterized a Neurospora crassa gene homologous to the yeast CYH2 gene encoding L29, a cycloheximide sensitivity-conferring protein of the cytoplasmic ribosome. The cloned Neurospora gene was isolated by cross-hybridization to CYH2. It was sequenced from both cDNA and genomic clones. The coding region is interrupted by seven intervening sequences. Its deduced amino acid sequence shows 70% homology to that of yeast ribosomal protein L29 and 60% homology to that of mammalian ribosomal protein L27', suggesting that the protein has an important role in ribosomal function. The pattern of codon usage is highly biased, consistent with high translation efficiency. There is a single copy of this gene in N. crassa, and R. Metzenberg and coworkers have mapped its genetic location to the vicinity of the cyh-2 locus.     

Adaptive basis of codon usage in the haploid moss Physcomitrella patens

Patterns of codon usage bias were studied in the moss model species Physcomitrella patens. A total of 92 nuclear, protein coding genes were employed, and estimated levels of gene expression were tested for association with two measures of codon usage bias and other variables hypothesized to be associated with gene expression. Codon bias was found to be positively associated both with estimated levels of gene expression and GC content in the coding parts of studied genes. However, GC content in noncoding parts, that is, introns and 5' and 3' untranslated regions (UTRs), was not associated with estimated levels of gene expression. It is argued that codon bias is not shaped by mutational bias, but rather by weak natural selection for translational efficiency in P. patens. The possible role of life history characteristics in shaping patterns of codon usage in this species is discussed.