Substrate-induced differential degradation and partitioning of the two tryptophan permeases Tat1 and Tat2 into eisosomes in Saccharomyces cerevisiae.

Tryptophan is a relatively rare amino acid whose influx is strictly controlled to meet cellular demands. The yeast Saccharomyces cerevisiae has two tryptophan permeases, namely Tat1 (low-affinity type) and Tat2 (high-affinity type). These permeases are differentially regulated through ubiquitination based on inducible conditions and dependence on arrestin-related trafficking adaptors, although the physiological significance of their degradation remain unclear. Here, we demonstrated that Tat2 was rapidly degraded in an Rsp5-Bul1-dependent manner upon the addition of tryptophan, phenylalanine, or tyrosine, whereas Tat1 was unaffected. The expression of the ubiquitination-deficient variant Tat25K>R led to a reduction in cell yield at 4 µg/mL tryptophan, suggesting the occurrence of an uncontrolled, excessive consumption of tryptophan at low tryptophan concentrations. Eisosomes are membrane furrows that are thought to be storage compartments for some nutrient permeases. Tryptophan addition caused rapid Tat2 dissociation from eisosomes, whereas Tat1 distribution was unaffected. The 5 K > R mutation had no marked effect on Tat2 dissociation, suggesting that dissociation is independent of ubiquitination. Interestingly, the D74R mutation, which was created within the N-terminal acidic patch, stabilized Tat2 while reducing the degree of partitioning into eisosomes. Moreover, the hyperactive I285V mutation in Tat2, which increases Vmax/Km for tryptophan import by 2-fold, reduced the degree of segregation into eisosomes. Our findings illustrate the coordinated activity of Tat1 and Tat2 in the regulation of tryptophan transport at various tryptophan concentrations and suggest the positive role of substrates in inducing a conformational transition in Tat2, resulting in its dissociation from eisosomes and subsequent ubiquitination-dependent degradation.

A novel ER membrane protein Ehg1/May24 plays a critical role in maintaining multiple nutrient permeases in yeast under high-pressure perturbation.

Previously, we isolated 84 deletion mutants in Saccharomyces cerevisiae auxotrophic background that exhibited hypersensitive growth under high hydrostatic pressure and/or low temperature. Here, we observed that 24 deletion mutants were rescued by the introduction of four plasmids (LEU2, HIS3, LYS2, and URA3) together to grow at 25 MPa, thereby suggesting close links between the genes and nutrient uptake. Most of the highly ranked genes were poorly characterized, including MAY24/YPR153W. May24 appeared to be localized in the endoplasmic reticulum (ER) membrane. Therefore, we designated this gene as EHG (ER-associated high-pressure growth gene) 1. Deletion of EHG1 led to reduced nutrient transport rates and decreases in the nutrient permease levels at 25 MPa. These results suggest that Ehg1 is required for the stability and functionality of the permeases under high pressure. Ehg1 physically interacted with nutrient permeases Hip1, Bap2, and Fur4; however, alanine substitutions for Pro17, Phe19, and Pro20, which were highly conserved among Ehg1 homologues in various yeast species, eliminated interactions with the permeases as well as the high-pressure growth ability. By functioning as a novel chaperone that facilitated coping with high-pressure-induced perturbations, Ehg1 could exert a stabilizing effect on nutrient permeases when they are present in the ER.

Hyperactive mutation occurs adjacent to the essential glutamate 286 for transport in the yeast tryptophan permease Tat2.

In Saccharomyces cerevisiae, high-affinity tryptophan import is mediated by the plasma membrane permease Tat2. Herein, we identified hyperactive Tat2 mutations, I285V and I285T, which allowed the cells to grow at very low tryptophan concentrations (<4 µg/mL). The Km value of wild-type Tat2 for tryptophan appeared to be 24 µg/mL, whereas that of Tat2I285V and Tat2I285T was 17 and 11 µg/mL, respectively. Normalized values of Vmax/Km for Tat2I285V- and Tat2I285T-mediated tryptophan import were 2-fold higher than that for Tat2, suggesting that these mutations increase the affinity for tryptophan, and mediate transport at very low tryptophan concentrations. I285 resides adjacent to E286, a fully conserved residue among amino acid pemreases. According to a pKa prediction for E208 (pKa ∼8.3-11.7) of Escherichia coli AdiC antiporter, a structural homologue of Tat2, the E286 carboxyl chain of Tat2 could get loaded with a proton during tryptophan/H+ symport. Hence, I285V and I285T mutations might affect the buried residue environment of Tat2, thereby facilitating tryptophan import. Additionally, Tat2I285V and Tat2I285T levels increased rapidly, and were efficiently localized to the cell surface after transferring the cells to low tryptophan medium (0.5 µg/mL). Our findings provide a clue to gain insights into the property of high-affinity transport mechanisms, and offer a unique approach to improve the functionality of broad types of amino acid permeases.