Suppression of a nuclear aep2 mutation in Saccharomyces cerevisiae by a base substitution in the 5'-untranslated region of the mitochondrial oli1 gene encoding subunit 9 of ATP synthase.

Mutations in the nuclear AEP2 gene of Saccharomyces generate greatly reduced levels of the mature form of mitochondrial oli1 mRNA, encoding subunit 9 of mitochondrial ATP synthase. A series of mutants was isolated in which the temperature-sensitive phenotype resulting from the aep2-ts1 mutation was suppressed. Three strains were classified as containing a mitochondrial suppressor: these lost the ability to suppress aep2-ts1 when their mitochondrial genome was replaced with wild-type mitochondrial DNA (mtDNA). Many other isolates were classified as containing dominant nuclear suppressors. The three mitochondrion-encoded suppressors were localized to the oli1 region of mtDNA using rho- genetic mapping techniques coupled with PCR analysis; DNA sequencing revealed, in each case, a T-to-C nucleotide transition in mtDNA 16 nucleotides upstream of the oli1 reading frame. It is inferred that the suppressing mutation in the 5' untranslated region of oli1 mRNA restores subunit 9 biosynthesis by accommodating the modified structure of Aep2p generated by the aep2-ts1 mutation (shown here to cause the substitution of proline for leucine at residue 413 of Aep2p). This mode of mitochondrial suppression is contrasted with that mediated by heteroplasmic rearranged rho- mtDNA genomes bypassing the participation of a nuclear gene product in expression of a particular mitochondrial gene. In the present study, direct RNA-protein interactions are likely to form the basis of suppression.

The mature AEP2 gene product of Saccharomyces cerevisiae, required for the expression of subunit 9 of ATP synthase, is a 58 kDa mitochondrial protein.

The nucleotide sequence of the yeast nuclear AEP2 gene, required for the expression of the mitochondrial DNA-encoded subunit 9 of ATP synthase, predicts a primary translation product of 67.5 kDa. The ATP13 gene is allelic to AEP2 but was reported to encode a protein of about 42 kDa in size. We thus investigated genetically and biochemically the size of the AEP2 gene product. Genetic complementation assays using 3' truncated AEP2 genes, here shows that function is abolished by the removal of only 32 amino acids from the C-terminus of the predicted protein product. Cell-free translation of AEP2 produces a 64 kDa polypeptide (consistent with the AEP2 sequence) which is imported into mitochondria and processed to a 58 kDa product by the removal of a presequence of about 50 amino acids.

Reactivity of potassium permanganate and tetraethylammonium chloride with mismatched bases and a simple mutation detection protocol.

Many mutation detection techniques rely upon recognition of mismatched base pairs in DNA hetero-duplexes. Potassium permanganate in combination with tetraethylammonium chloride (TEAC) is capable of chemically modifying mismatched thymidine residues. The DNA strand can then be cleaved at that point by treatment with piperidine. The reactivity of potassium permanganate (KMnO4) in TEAC toward mismatches was investigated in 29 different mutations, representing 58 mismatched base pairs and 116 mismatched bases. All mismatched thymidine residues were modified by KMnO4/TEAC with the majority of these showing strong reactivity. KMnO4/TEAC was also able to modify many mismatched guanosine and cytidine residues, as well as matched guanosine, cytidine and thymidine residues adjacent to, or nearby, mismatched base pairs. Previous techniques using osmium tetroxide (OsO4) to modify mismatched thymidine residues have been limited by the apparent lack of reactivity of a third of all T/G mismatches. KMnO4/TEAC showed no such phenomenon. In this series, all 29 mutations were detected by KMnO4/TEAC treatment. The latest development of the Single Tube Chemical Cleavage of Mismatch Method detects both thymidine and cytidine mismatches by KMnO4/TEAC and hydroxylamine (NH2OH) in a single tube without a clean-up step in between the two reactions. This technique saves time and material without disrupting the sensitivity and efficiency of either reaction.

Chemical cleavage of mismatch: a new look at an established method.

Chemical cleavage of mismatch (CCM), also known as chemical mismatch cleavage (CMC) or the HOT (hydroxylamine/osmium tetroxide) chemical method, has been used for detection of sequence variability with many systems since it was first described. Recently, adaptation to fluorescence-based detection systems has fundamentally changed both the execution and analysis of CCM. This review will outline major advances in the methodology of CCM, from the advent of PCR through fluorescent analysis, and includes applications and modifications of CCM.