Gln3, the major activator of nitrogen catabolite repression (NCR)-sensitive transcription, is often used as an assay of Tor pathway regulation in Saccharomyces cerevisiae. Gln3 is cytoplasmic in cells cultured with repressive nitrogen sources (Gln) and nuclear with derepressive ones (Pro) or after treating Glngrown cells with the Tor inhibitor, rapamycin (Rap). In Raptreated or Pro-grown cells, Sit4 is posited to dephosphorylate Gln3, which then dissociates from a Gln3-Ure2 complex and enters the nucleus. However, in contrast with this view, Sit4-dependent Gln3 dephosphorylation is greater in Gln than Pro. Investigating this paradox, we show that PP2A (another Tor pathway phosphatase)-dependent Gln3 dephosphorylation is regulated oppositely to that of Sit4, being greatest in Pro-and least in Gln-grown cells. It thus parallels nuclear Gln3 localization and NCR-sensitive transcription. However, because PP2A is not required for nuclear Gln3 localization in Pro, PP2A-dependent Gln3 dephosphorylation and nuclear localization are likely parallel responses to derepressive nitrogen sources. In contrast, Rap-induced nuclear Gln3 localization absolutely requires all four PP2A components (Pph21/22, Tpd3, Cdc55, and Rts1). In pph21⌬22⌬, tpd3⌬, or cdc55⌬ cells, however, Gln3 is dephosphorylated to the same level as in Rap-treated wildtype cells, indicating Rap-induced Gln3 dephosphorylation is insufficient to achieve nuclear localization. Finally, PP2A-dependent Gln3 dephosphorylation parallels conditions where Gln3 is mostly nuclear, while Sit4-dependent and Rap-induced dephosphorylation parallels those where Gln3 is mostly cytoplasmic, suggesting the effects of these phosphatases on Gln3 may occur in different cellular compartments. (Tor) 2 is widely acknowledged as a global regulator whose actions control and integrate an array of cellular processes ranging from transcription to cell division (1-4). One of the principal roles of Tor is participation in the adjustment of cell metabolism and cell biology to intra-and extracellular nutrient fluctuations. Investigation of the Saccharomyces cerevisiae Tor proteins (Tor1 and Tor2) has added much to our understanding of their mammalian homologue (mTor) (1). Central to many of these investigations has been the GATA-binding transcriptional activator, Gln3, well known for its control of nitrogen catabolite repression (NCR)-sensitive transcription (5-9).
Target of RapamycinNitrogen Catabolite Repression in S. cerevisiae-NCR is the regulatory mechanism through which S. cerevisiae responds to environmental nitrogen availability and selectively utilizes good nitrogen sources in preference to poorer ones (5-9). It permits cells to rapidly and successfully cope with nutritional changes ranging from starvation after a rain storm to luxurious nitrogen excess when situated in decaying fruit. NCR-sensitive regulation is achieved by controlling the action of Gln3. When cells are growing in the presence of sufficient quantities of a good nitrogen source (e.g. glutamine), Gln3 is restricted to ...
