Pse1/Kap121-dependent nuclear localization of the major yeast multidrug resistance (MDR) transcription factor Pdr1.

Pdr1 and Pdr3 are two very similar transcription factors that mainly control membrane biogenesis by adjusting the production of different membrane proteins, such as different ABC or major facilitator superfamily (MFS) transporters. We observed that the pse1-1 mutation in the importin/beta-karyopherin Pse1/Kap121 specifically induced the cytoplasmic localization of Pdr1, but not that of Pdr3. Interactions between Pse1 and Pdr1 could be observed in vivo, and a short peptide of 44 amino acids from Pdr1 was shown to contain the information necessary and sufficient for Pse1-dependent nuclear import. This Pdr1-NLS sequence, absent in Pdr3, although rich in serine and tyrosine, is different from the Pse1-dependent nuclear localization signal (NLS) of Pho4. Furthermore, we showed that Pse1/Kap121 is likely to be the sole import receptor for the regulator Pdr1. Together, these new observations underscore the diversity of cellular processes that address to the nucleus two very similar transcription factors involved in the control of the same phenotype, thus securing their function in the cell.

The pdr12 ABC transporter is required for the development of weak organic acid resistance in yeast.

Exposure of Saccharomyces cerevisiae to sorbic acid strongly induces two plasma membrane proteins, one of which is identified in this study as the ATP-binding cassette (ABC) transporter Pdr12. In the absence of weak acid stress, yeast cells grown at pH 7.0 express extremely low Pdr12 levels. However, sorbate treatment causes a dramatic induction of Pdr12 in the plasma membrane. Pdr12 is essential for the adaptation of yeast to growth under weak acid stress, since Deltapdr12 mutants are hypersensitive at low pH to the food preservatives sorbic, benzoic and propionic acids, as well as high acetate levels. Moreover, active benzoate efflux is severely impaired in Deltapdr12 cells. Hence, Pdr12 confers weak acid resistance by mediating energy-dependent extrusion of water-soluble carboxylate anions. The normal physiological function of Pdr12 is perhaps to protect against the potential toxicity of weak organic acids secreted by competitor organisms, acids that will accumulate to inhibitory levels in cells at low pH. This is the first demonstration that regulated expression of a eukaryotic ABC transporter mediates weak organic acid resistance development, the cause of widespread food spoilage by yeasts. The data also have important biotechnological implications, as they suggest that the inhibition of this transporter could be a strategy for preventing food spoilage.

Endocytosis and vacuolar degradation of the plasma membrane-localized Pdr5 ATP-binding cassette multidrug transporter in Saccharomyces cerevisiae.

Multidrug resistance (MDR) to different cytotoxic compounds in the yeast Saccharomyces cerevisiae can arise from overexpression of the Pdr5 (Sts1, Ydr1, or Lem1) ATP-binding cassette (ABC) multidrug transporter. We have raised polyclonal antibodies recognizing the yeast Pdr5 ABC transporter to study its biogenesis and to analyze the molecular mechanisms underlying MDR development. Subcellular fractionation and indirect immunofluorescence experiments showed that Pdr5 is localized in the plasma membrane. In addition, pulse-chase radiolabeling of cells and immunoprecipitation indicated that Pdr5 is a short-lived membrane protein with a half-life of about 60 to 90 min. A dramatic metabolic stabilization of Pdr5 was observed in delta pep4 mutant cells defective in vacuolar proteinases, and indirect immunofluorescence showed that Pdr5 accumulates in vacuoles of stationary-phase delta pep4 mutant cells, demonstrating that Pdr5 turnover requires vacuolar proteolysis. However, Pdr5 turnover does not require a functional proteasome, since the half-life of Pdr5 was unaffected in either pre1-1 or pre1-1 pre2-1 mutants defective in the multicatalytic cytoplasmic proteasome that is essential for cytoplasmic protein degradation. Immunofluorescence analysis revealed that vacuolar delivery of Pdr5 is blocked in conditional end4 endocytosis mutants at the restrictive temperature, showing that endocytosis delivers Pdr5 from the plasma membrane to the vacuole.

Egg yolk alpha-livetin (chicken serum albumin) is a cross-reactive allergen in the bird-egg syndrome.

Thirty-one patients with clinical history of egg allergy, bird allergy, or bird and egg allergy were investigated with the use of the immunoblot technique to compare IgE-binding components in bird feather and egg yolk and white extracts. Patients were classified into three groups according to clinical history, skin prick test results, and RAST results. Patients in group I were sensitized to bird feathers and egg yolk, patients in group II to egg white, and patients in group III to bird feather but not to eggs. Patients with bird-egg syndrome were mainly female adults, whereas egg white allergy was mainly observed in children without any obvious sex predisposition. IgE from patients with bird-egg syndrome recognized a 70 kd protein in egg yolk (chicken serum albumin = alpha-livetin) and some major allergens in bird feather extract (70, 95, and 200 kd). Preincubation of pooled sera from patients with bird-egg syndrome with budgerigar or hen feather extract and egg yolk extract, respectively, led to complete blocking of IgE binding to allergens in egg yolk and bird feather extract. On the other hand, IgE from patients with egg white allergy did not react with allergens in egg yolk and bird feather extract, despite strong IgE binding to egg white allergens. Patients in group III displayed no reactivity to bird feather or egg allergens. Our results demonstrate common epitopes of budgerigar and hen feather and egg yolk alpha-livetin. Therefore we assume that alpha-livetin (chicken serum albumin) leads to a cross-sensitization and consequently to the "bird-egg syndrome."