Translation in a wheat germ cell-free system of RNA from mitochondria of the normal and Texas male-sterile cytoplasms of maize (Zea mays L.)

Regulation of gene expression in plant mitochondria

Many genes is plant mitochondria have been analyzed in the past 15 years and regulatory processes controlling gene expression can now be investigated. In vitro systems capable of initiating transcription faithfully at promoter sites have been developed for both monocot and dicot plants and will allow the identification of the interacting nucleic acid elements and proteins which specify and guide transcriptional activities. Mitochondrial activity, although required in all plant tissues, is capable of adapting to specific requirements by regulated gene expression. Investigation of the factors governing the quality and quantity of distinct RNAs will define the extent of interorganelle regulatory interference in mitochondrial gene expression.

MRG1-1, a dominant allele that confers methomyl resistance in yeast expressing the cytoplasmic male sterility T-urf13 gene from maize

We have previously described a eukaryotic heterologous expression system, with the urf13TW gene in yeast, which mimics the disease susceptibility associated with the Texas cytoplasmic male sterility in maize. This yeast model was used to isolate yeast nuclear mutants conferring methomyl resistance. The genetic strategy we have developed focused on screening for nuclear dominant yeast mutations which restore methomyl resistance. MRG1-1, a yeast nuclear dominant allele, was identified as a methomyl-resistance restorer. We have shown that methomyl resistance co-segregated with a pleiotropic phenotype in the heterozygous MRG1-1/MRG1 diploids, detectable even in the absence of the maize-derived mitochondrial protein and/or methomyl. We observed an increase in oxygen uptake, a significant decrease of the levels of cytochrome aa3, and a decrease in the growth yield. This phenotype is influenced by the carbon source and the results suggest a defect in the adaptation to the respiratory pathway in MRG1-1 yeast cells.