Transcription of the S-2 maize mitochondrial plasmid

Characterization of a novel thermosensitive restorer of fertility for cytoplasmic male sterility in maize

S-type cytoplasmic male sterility (CMS-S) in maize is associated with high levels of a 1.6-kb RNA in mitochondria. This RNA contains two chimeric open reading frames (ORFs), orf355 and orf77. The previously described nuclear restorer-of-fertility allele Rf3 causes the processing of all transcripts that contain these chimeric ORFs. The Lancaster Surecrop-derived inbred line A619 carries a restorer that is distinct from Rf3 in that it selectively reduces only the CMS-S-specific 1.6-kb RNA. We have found that 10 additional Lancaster lines carry a single restoring allele traceable to either of two inbred lines, C103 and Oh40B. The C103 and Oh40B restorers are allelic to each other, but not to Rf3. Thus, this restoring allele, designated Rf9, represents a second naturally occurring CMS-S restorer in maize. Rf9 is a less effective restorer of fertility than is Rf3; its expression is influenced by both inbred nuclear background and temperature. Rf9 acts to reduce the amounts of orf355/orf77-containing linear mitochondrial subgenomes, which are generated by recombination of circular subgenomes with CMS-S-specific linear plasmids. The 1.6-kb RNA, which is transcribed only from linear ends, is correspondingly reduced.

Linear plasmids in plant mitochondria: peaceful coexistences or malicious invasions?

Plant mitochondria contain small extrachromosomal DNAs in addition to a large and complex main mitochondrial genome. These molecules can be regarded as extrachromosomal replicons or plasmids, of which there are two forms, circular and linear. Linear mitochondrial plasmids are present in many fungi and in some plants, but they seem to be absent from most animal cells. They usually have a common structural feature, called an invertron, that is characterized by the presence of terminal inverted repeats and proteins covalently attached to their 5 termini. Linear mitochondrial plasmids possess one to six ORFs that can encode unknown proteins but often code for the DNA and RNA polymerases. Although the functions of most linear plasmids in plant mitochondria are unknown, some plasmids may be associated with mitochondrial genome rearrangements and may have phenotypic effects due to their integration into mitochondrial genome. The Brassica 11.6-kb plasmid, one of the linear mitochondrial plasmids in plants, shows a non-maternal inheritance, in contrast to mitochondrial genomes. The origin of these plasmids is still a mystery, but indirect evidence indicates the possibility of horizontal transfer from fungal mitochondria. In this review, the main features of these unique DNAs present in plant mitochondria are described.

Involvement of S2 episomal sequences in the generation of NCS4 deletion mutation in maize mitochondria

Cytoplasmic male sterility (CMS) and the abnormal-growth, nochromosomal stripe (NCS) phenotypes are cytoplasmically determined traits in plants. Mitochondrial DNA rearrangements involving short repeats appear to be responsible for the production of CMS reversions to fertility and NCS mutations. NCS4, a new mutant of maize CMS-S, exhibits both abnormal growth and male fertility. This mutant is unique because both mutations occurred within the same plant. Free S1 and S2 episomes normally found in CMS-S mitochondria have been lost from NCS4 plants. An S2 sequence has recombined aberrantly with a ribosomal protein coding region, rps3/rpl16. One end of the S2 sequence and the 5' end of the rps3/rpl16 transcription unit are absent from the NCS4 recombinant genome. Loss of mitochondrial ribosomal protein function is lethal; therefore, NCS4 plants are heteroplasmic for the rps3 deletion. Loss of S sequences from CMS-S mitochondria is not lethal and plants regain pollen function. Thus, although NCS4 plants have very abnormal plant phenotypes, they are male-fertile.

A gene from the fungal plant pathogen Nectria haematococca that encodes the phytoalexin-detoxifying enzyme pisatin demethylase defines a new cytochrome P450 family

The gene PDAT9 from the fungus Nectria haematococca encodes pisatin demethylase, an enzyme that detoxifies the phytoalexin pisatin, an antimicrobial compound produced by pea in response to infection by this plant pathogen. PDAT9 was found to contain an open reading frame (ORF) encoding 515 amino acids and four introns of 52-58 nucleotides each within its coding region. The amino acid sequence F-G-A-G-S-R-S-C-I-G, indicative of the "fifth ligand binding site" present in all cytochrome P450s, occurs as residues 446 to 455, confirming that PDAT9 is a cytochrome P450. The deduced amino acid sequence is distinct from all other reported cytochrome P-450s, and PDAT9 has been assigned to a new cytochrome P450 family, CYP57. A 1.3 kb SacI fragment of the PDAT9 ORF that lacked the fifth ligand binding site, hybridized to unique DNA fragments in N. haematococca isolates known to possess PDA genes that encode different whole cell phenotypes for pisatin demethylating activity. These genes were also tentatively identified as cytochrome P450s by the hybridization of the same fragments to separate subclones of PDAT9, one of which contained the fifth ligand sequence. That probe also hybridized to DNA other than that attributed to pisatin demethylase genes; these other DNAs are presumed to represent other cytochrome P450s.

R-type plasmids in mitochondria from a single source of Zea luxurians teosinte

Two linear DNA plasmids resembling the R1 and R2 plasmids that are present in the mitochondria of several South American strains of maize were found in mitochondria from a single source of Zea luxurians collected by L. Mazoti. The Mazoti mtDNA is closely related to mtDNAs of other Z. luxurians, but mitochondria derived from the other Z. luxurians sources lack the plasmids. The larger plasmid from Mazoti mitochondria, M1, was cloned and large portions of it were sequenced. Restriction mapping and sequence comparisons showed that approximately 4.9 kb is similar to the S1 plasmid of maize and an additional 2.6 kb is related to R1 sequences integrated into the main mitochondrial genome of N cytoplasm. Therefore, the M1 plasmid appears to be very similar to the R1 plasmid. The inverted repeats at the ends of the M1 plasmid are not identical. The left end IR is similar to the S-TIRs found at the termini of the S plasmids. The right end IR more closely resembles the integrated R1 sequences, including the "variant" region of the TIR. Whereas the variant region contains 13 bp in the S-TIRs and 15 bp in an integrated version of R1, it is 16 bp long in M1. The region of M1 that has no homology to the S1 plasmid is expressed at very low levels in Mazoti and RU cytoplasms, but at much higher levels in CMS-S mitochondria, where part of it is present in the main mitochondrial genome.

RFLP analysis of nuclear DNAs homologous with mitochondrial plasmid-like DNAs in cultivated rice

B1 and B2 are small, circular, mitochondrial plasmid-like DNAs found in male-sterile cytoplasm (cms-Bo) of rice. In this study, nuclear sequences homologous to these DNAs were investigated among a number of rice cultivars. Several copies of nuclear B1-and B2-homologous sequences were detected in all examined cultivars, regardless of the presence or absence of the B1 and B2 DNAs in mitochondria, indicating that the existence of the B1- and B2-homologous sequences in the rice nuclear genome was widespread. A restriction fragment length polymorphism (RFLP) was detected for both sequences, and we propose that these DNAs could be useful RFLP markers for the rice nuclear genome. To analyze these nuclear homologues genetically, segregation analysis of the RFLP was carried out in the F2 progenies of an Indica-Japonica rice hybrid. Of the B1 homologues, there were two nonallelic fragments, one specific to the Indica parent and the other to the Japonica. These results indicate that the B1 and B2 homologues were dispersed in the nuclear genome. The integration of B1-homologous DNA into the nuclear DNA may have occurred independently after sexual isolation of the Indica and Japonica rice varietal groups, or a intranuclear transposition of these sequences took place during the process of rice differentiation into the varietal groups.

Identification in maize mitochondrial 26S rRNA of a short 5'-end sequence possibly involved in transcription initiation and processing

By direct RNA mapping, we have identified the precise 5' end of the maize mitochondrial 26S rRNA. The 5' termini of the 26S rRNA are 17 and 18 nt downstream from the 5' end predicted by Dale et al. (1984) from homology between the maize rRNA and E. coli large subunit ribosomal RNA. In addition, we have discovered a larger 26S species, presumably a 26S precursor, and precisely mapped its 5' end. The maize mitochondrial rRNA genes are probably regulated by control regions that differ from those already characterized in other genomes: the maize mitochondrial 26S, 18S and 5S rRNAs lack sequences that resemble the promoter regions of genes from other mitochondria and bacteria. However, the mature and precursor rRNAs all contain a tetranucleotide, AAUC, at their 5' ends (AAAC in the 5S rRNA). The sequence is also seen in the same position in several other plant mitochondrial mRNAs. We propose therefore that AAUC is a transcription or processing signal which is possibly unique to plant mitochondria.