A mutation in the yeast mitochondrial ribosomal protein Rml2p is associated with a defect in catalase gene expression.

Yeast strains containing a new temperature-sensitive allele of the RML2 gene, encoding a component of the large subunit of the mitochondrial ribosome, display normal growth on acetate, slowed growth on glycerol and an inability to grow on oleic acid. These cells, denoted rml2(fat21), have an apparent inability to induce peroxisomal function, as evidenced by a deficiency in oleic acid induction of beta-oxidation. However, the oleic acid regulation of genes encoding core enzymes of peroxisomal beta-oxidation is normal. In contrast, up-regulation of CTA1 (catalase) mRNA expression and enzyme activity is interrupted. Upon comparison of the induction requirements of catalase and the genes of beta-oxidation, we hypothesized that the rml2(fat21) mutation alters the activity of the transcription factor Adr1p. In support of this hypothesis, over-expression of ADR1 in rml2(fat21) cells restores CTA1 induction. Several assays of mitochondria from rml2(fat21) strains suggest normal mitochondrial function. Thus, the modulation of Adr1p-associated gene regulation is not due to overt mitochondrial dysfunction.

A yeast strain defective in oleic acid utilization has a mutation in the RML2 gene.

The molecular mechanisms of cellular long-chain fatty acid assimilation and its regulation remain unclear. In an attempt to identify essential mediators of these processes, we have isolated mutant strains of the yeast Saccharomyces cerevisiae unable to utilize oleic acid as sole carbon source, while retaining the ability to utilize acetate. These strains are then subjected to several secondary screening assays to identify mutants of interest. Here we describe a mutant (denoted fat21) that, despite a temperature-sensitive inability to utilize oleic acid as sole carbon source, displays no general defect in oleic acid uptake or incorporation of oleic acid into glycerolipids. Oxidation of acetate after growth in acetate medium is increased similarly in the mutant and parent strains. Oleic acid beta-oxidation in acetate grown cells is also comparable between strains. Induction of oleic acid oxidation following exposure to oleic acid is, however, defective in the fat21 mutant. The fat21 mutant allele displays conditional synthetic lethality in combination with a null allele of the OLE1 gene, which encodes Delta9-desaturase and is required for proper mitochondrial segregation. Clones capable of complementing the fat21 defect contained the RML2 gene, encoding a yeast mitochondria ribosomal protein. Segregation analysis and gene replacement experiments demonstrate that RML2 is the gene defective in the fat21 mutant. These observations of a defect in a mitochondrial protein differentially affecting the adaptation to oleic acid and acetate as carbon sources suggest that the phenotype of fat21 is associated with a novel pathway of mitochondrial-nuclear-peroxisomal communication.

Effect of 12-O-tetradecanoylphorbol-13-acetate on inhibition of expression of keratin 1 mRNA in mouse keratinocytes mimicked by 12(S)-hydroxyeicosatetraenoic acid.

Differentiation of cultured keratinocytes is controlled by the calcium concentration of the medium and is marked by the expression of differentiation-specific keratins. Treatment with 12-O-tetradecanoylphorbol-13-acetate (TPA) alters the normal differentiation program and suppresses keratin (K) 1 expression. Based on reported similarities in the effects of TPA and the arachidonic acid metabolite 12(S)-hydroxyeicosatetraenoic acid (12(S)-HETE), we hypothesized that 12(S)-HETE might suppress K1 expression in mouse keratinocytes. We also investigated the effect of pretreatment with 13(S)-hydroxyoctadecadienoic acid (13(S)-HODE) because others have reported that 13(S)-HODE prevents 12(S)-HETE-induced events. In our study, 100 nM 12(S)-HETE mimicked the effect of 500 nM TPA in suppressing K1 mRNA expression within 24 h of calcium-induced differentiation. Pretreatment with 100 nM 13(S)-HODE blocked the 12(S)-HETE effect but not the TPA effect. A role for protein kinase C (PKC) was suggested for both TPA and 12(S)-HETE based on the loss of response with the PKC inhibitors bryostatin-1 or RO-31-8220. Both TPA and 12(S)-HETE stimulated keratinocyte PKC activity. Pretreatment with 13(S)-HODE blocked the 12(S)-HETE-induced increase in PKC activity. Immunoblotting showed that whereas TPA caused a rapid, partial translocation of the PKC alpha isozyme, it had no effect on the distribution of PKC delta. Conversely, 12(S)-HETE had no effect on the distribution of PKC alpha but caused a complete translocation of PKC delta. Pretreatment with 13(S)-HODE prevented 12(S)-HETE-elicited translocation of PKC delta. We conclude that 12(S)-HETE mimics the effect of TPA on K1 mRNA and that the effect is mediated through different isoforms of PKC.

Arachidonate has protumor-promoting action that is inhibited by linoleate in mouse skin carcinogenesis.

Previous studies demonstrated a requirement for arachidonic acid metabolites in tumor development in mouse skin. The goal of this study was to determine whether the arachidonate content of epidermal phospholipids could be altered by increasing dietary levels of linoleate and whether specific metabolites of linoleate and arachidonate have dissimilar biological effects. In a series of tumor studies in which the quantity of dietary linoleate was incrementally increased, a slight reduction in phospholipid levels of arachidonate was observed that correlated with an increased phospholipid level of linoleate and a suppression in tumor yield. A comparison of the arachidonate lipoxygenase metabolite 12-hydroxyeicosatetraenoic acid (12-HETE) with the 13-hydroxyoctadecadienoic acid (13-HODE) lipoxygenase metabolite of linoleate revealed that 12-HETE has biological activities that mimic the phorbol ester tumor promoters, whereas 13-HODE has antithetical effects. Specifically, 12(S)-HETE enhanced the activation of protein kinase C by phorbol esters, mimicked phorbol ester-induced adhesion of keratinocytes to fibronectin and mimicked phorbol ester repression of expression of a differentiation-related gene, keratin-1. 13-HODE blocked 12-HETE-induced cell adhesion and prevented 12-HETE-induced suppression of keratin-1 expression. Overall, these studies suggest that arachidonate and linoleate have opposing functions in the epidermis, particularly with regard to events involved in tumor development.