Processing of precursor RNAs from mitochondria of Neurospora crassa

Regulation of cytochrome c oxidase subunit 1 (COX1) expression in Cryptococcus neoformans by temperature and host environment

In the study of differential gene expression of Cryptococcus neoformans, a transcript of COX1 (cytochrome oxidase c subunit 1) was identified in a serotype A strain. The transcript was upregulated at 37 degrees C compared to 30 degrees C and expressed by yeasts infecting the central nervous system. Northern analysis of COX1 from the serotype A strain revealed two polycistronic transcripts, a temperature-upregulated 2.3 kb transcript and a 1.9 kb transcript that was not affected by temperature. In contrast, COX1 in a serotype D strain showed only a 1.9 kb polycistronic transcript plus a 1.6 kb monocistronic message, and temperature had no effect on the transcripts. The sequence of COX1 revealed similar coding regions between the two strains, but the serotype D strain had five introns whereas no introns were found in the serotype A strain. The serotype D strain had reduced growth rates compared to the serotype A strain at 37 degrees C, but in an AD hybrid strain the serotype D COX1 gene could support efficient high temperature growth. These studies have revealed mitochondrial molecular differences between serotype A and D strains which show evolutionary divergence. It will be important to determine whether differences in mitochondrial structure and function can influence cryptococcosis.

mRNA expression in mitochondria of the red alga chondrus crispus requires a unique RNA-processing mechanism, internal cleavage of upstream tRNAs at pyrimidine 48

The hypothesis that tRNAs are involved in the maturation of the large primary transcripts of Chondrus crispus mitochondrial DNA was addressed by primer extension mapping of the transcript 5' ends of the ten genes that are preceded by tRNA genes in C. crispus mitochondrial genome. Among the 12 tRNAs that were candidates as maturation signals, eight, namely tRNAArg, tRNALys, tRNAAsp, tRNAGln, tRNATrp, tRNAIle, tRNAPhe and tRNAGly, were cleaved internally upon maturation of C. crispus mitochondrial primary transcripts, all of them at the same base, invariant pyrimidine 48. Only four tRNAs departed from this pattern: tRNALeu and tRNACys, which are not maturation signals, tRNAMet, which appears to be excised as a whole from the orf94 primary trancript and tRNAAla, which is cleaved internally at positions other than Y48. Sequence comparisons between the cleaved and the uncleaved tRNAs suggest that their core tertiary structure is involved with their recognition and cleavage. However, the precursor transcripts are also processed at the 5' and 3' ends of the tRNAs to yield tRNA molecules that are stable and functional in translation. This indicates that two different RNA processing mechanisms coexist in C. crispus mitochondria, one required for the production of functional tRNAs and the other for the processing of mRNAs.

Transcript mapping and processing of mitochondrial RNA in the chlorophyte alga Prototheca wickerhamii

The detailed transcript map of the circular 55328 bp mitochondrial (mt) genome from the colourless chlorophycean alga Prototheca wickerhamii has been determined. On each half of this genome the genes are encoded only on one DNA strand, forming transcriptional units comprising variable numbers of genes. With the exception of four genes coding for ribosomal proteins, transcripts of the three rRNA genes and all protein-coding genes have been detected by both northern analysis and primer extension experiments. Polycistronic transcripts of protein coding and tRNA genes were verified by northern analyses, primer extension and RNAse mapping experiments. The 5' and 3' ends of different RNA species are often located in close proximity to putative stem-loop structures and some 5' termini of mRNAs coincide with the 3' end of tRNAs located immediately upstream. Transcript mapping in a putative promoter region revealed two different possible transcription initiation sites; no significant sequence homology to putative mt promoters from higher plants could be found. In addition, two out of three group I introns residing in the cox1 gene were found to be self-splicing in vitro under reaction conditions developed for related mt introns from a filamentous fungus. Mitochondrial gene expression of P. wickerhamii and of filamentous fungi has several features in common, such as intron splicing and the processing of longer polycistronic transcripts. The similarities in RNA maturation between higher-plant and P. wickerhamii mitochondria are less pronounced, since plants rarely use tRNAs as processing signals for their relatively short mitochondrial co-transcripts.

Characterization of a novel plasmid-like element in Neurospora crassa derived mostly from the mitochondrial DNA

We have identified a plasmid-like element within mitochondria of Neurospora crassa strain stp-B1. It is derived from the EcoRI-4 and EcoRI-6 regions of the mitochondrial DNA, and an additional 124 bp DNA segment of unknown origin. The plasmid DNA consists of an oligomeric series of circular molecules of monomer length 2.2 kbp. The abundance of the plasmid suggests its autonomous replication and the presence of an efficient origin of replication. An unusually large number of palindromes capable of forming secondary structures are present in the plasmid. Such a palindrome, located near sequences reminiscent of mammalian and fungal mtDNA origins of replication, may define the replication origin of the plasmid. This putative origin might also represent the replication origin of the wild-type mtDNA.

Prediction of RNA secondary structure, including pseudoknotting, by computer simulation

A computer program is presented which determines the secondary structure of linear RNA molecules by simulating a hypothetical process of folding. This process implies the concept of 'nucleation centres', regions in RNA which locally trigger the folding. During the simulation, the RNA is allowed to fold into pseudoknotted structures, unlike all other programs predicting RNA secondary structure. The simulation uses published, experimentally determined free energy values for nearest neighbour base pair stackings and loop regions, except for new extrapolated values for loops larger than seven nucleotides. The free energy value for a loop arising from pseudoknot formation is set to a single, estimated value of 4.2 kcal/mole. Especially in the case of long RNA sequences, our program appears superior to other secondary structure predicting programs described so far, as tests on tRNAs, the LSU intron of Tetrahymena thermophila and a number of plant viral RNAs show. In addition, pseudoknotted structures are often predicted successfully. The program is written in mainframe APL and is adapted to run on IBM compatible PCs, Atari ST and Macintosh personal computers. On an 8 MHz 8088 standard PC without coprocessor, using STSC APL, it folds a sequence of 700 nucleotides in one and a half hour.

Mutations in nuclear gene cyt-4 of Neurospora crassa result in pleiotropic defects in processing and splicing of mitochondrial RNAs

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.

Processing of mitochondrial RNA in Aspergillus nidulans

Genes for cytochrome oxidase subunit I (oxiA), ATPase subunit 9, NADH dehydrogenase subunit 3 (ndhC) and cytochrome oxidase subunit II (oxiB) are located within a 7.2 kb (1 kb = 10(3) bases or base-pairs) segment of the Aspergillus nidulans mitochondrial genome. Northern hybridization shows that abundant RNA molecules of 4.0, 2.5 and 1.5 kb, each containing copies of two or more genes, are transcribed from this region. The 4.0 kb molecule, which contains copies of each of the four genes but lacks the three oxiA introns, is cleaved at a point just upstream from ndhC to give rise to the 2.5 kb RNA, which contains copies of oxiA and the ATPase subunit 9 gene, and the 1.5 kb RNA, which carries ndhC and oxiB. The ATPase subunit 9 gene, which has no identified function, is therefore transcribed into an abundant RNA. S1 nuclease analysis indicates that there are no additional introns in the amino-terminal region of oxiA and that the 4.0 and 2.5 kb transcripts of this gene have staggered 5' termini, the most upstream of which is adjacent to the 3' end of the histidinyl-tRNA gene. The results suggest that transcription of this genome proceeds via a very limited number of primary transcripts with mature RNAs produced by extensive processing events including tRNA excision. RNA synthesis and processing in A. nidulans mitochondria therefore resembles the events occurring in metazoa rather than yeast.

Duplication of the tRNA(MMet) and tRNA(Cys) genes and of fragments of a gene encoding a subunit of the NADH dehydrogenase complex in Neurospora grassa mitochondrial DNA

Neurospora crassa mitochondrial DNA (mtDNA) contains duplications of the tRNA(MMet) gene upstream of a gene (ND2) encoding a subunit of the NADH dehydrogenase complex and of the tRNA(Cys) gene which is found downstream of the apocytochrome b gene. Both duplicated genes are located upstream of the small rRNA gene. The duplications are extended to flanking sequences. In the case of the tRNA(MMet) duplication, two fragments of the ND2 gene are also duplicated. These two fragments, which are not contiguous in the ND2 gene, are connected to each other by a palindromic sequence of 37 bp and together they constitute an open reading frame. The possible involvement of this palindromic sequence in the processes of gene duplication and transfer is discussed. Two overlapping reading frames are present between the tRNA(MMet) and tRNA(Cys) copies. All information of the ND2 duplication and the two overlapping reading frames are present on a polycistronic transcript.