Macroautophagy (or autophagy) is a conserved degradative pathway that has been implicated in a number of biological processes, including organismal aging, innate immunity, and the progression of human cancers. This pathway was initially identified as a cellular response to nutrient deprivation and is essential for cell survival during these periods of starvation. Autophagy is highly regulated and is under the control of a number of signaling pathways, including the Tor pathway, that coordinate cell growth with nutrient availability. These pathways appear to target a complex of proteins that contains the Atg1 protein kinase. The data here show that autophagy in Saccharomyces cerevisiae is also controlled by the cAMP-dependent protein kinase (PKA) pathway. Elevated levels of PKA activity inhibited autophagy and inactivation of the PKA pathway was sufficient to induce a robust autophagy response. We show that in addition to Atg1, PKA directly phosphorylates Atg13, a conserved regulator of Atg1 kinase activity. This phosphorylation regulates Atg13 localization to the preautophagosomal structure, the nucleation site from which autophagy pathway transport intermediates are formed. Atg13 is also phosphorylated in a Tor-dependent manner, but these modifications appear to occur at positions distinct from the PKA phosphorylation sites identified here. In all, our data indicate that the PKA and Tor pathways function independently to control autophagy in S. cerevisiae, and that the Atg1/Atg13 kinase complex is a key site of signal integration within this degradative pathway.cAMP-dependent protein kinase ͉ macroautophagy ͉ stationary phase ͉ Tor protein kinase M acroautophagy (hereafter autophagy) is a highlyconserved membrane trafficking pathway that is responsible for the turnover of bulk cytoplasmic protein and organelles (1, 2). This pathway was initially identified as a cellular response to nutrient deprivation (3, 4). However, recent studies indicate that autophagy is involved in a wide variety of physiological processes, including tissue remodeling during development, the removal of protein aggregates, and innate immune responses (5, 6). During autophagy, an isolation membrane emanates from a nucleation site that is known as the preautophagosomal structure (PAS) in Saccharomyces cerevisiae and the phagophore assembly site in mammals (7,8). This double membrane encapsulates nearby cytoplasm and ultimately targets it to the vacuole/ lysosome for degradation. The breakdown products are then recycled to allow for the synthesis of the macromolecules needed for survival during the period of starvation (9). The cellular components mediating autophagy were initially described in S. cerevisiae, and orthologs of many of these Atg proteins have since been identified in other eukaryotes (10, 11).The flux through the autophagy pathway is tightly controlled by multiple signaling pathways, including the Tor pathway, that are responsible for coordinating cell growth with nutrient availability. One of the key targets of this control a...
Protein kinases are important mediators of much of the signal transduction that occurs in eukaryotic cells. Unfortunately, the identification of protein kinase substrates has proven to be a difficult task, and we generally know few, if any, of the physiologically relevant targets of any particular kinase. Here, we describe a sequence-based approach that simplified this substrate identification process for the cAMP-dependent protein kinase (PKA) in Saccharomyces cerevisiae. In this method, the evolutionary conservation of all PKA consensus sites in the S. cerevisiae proteome was systematically assessed within a group of related yeasts. The basic premise was that a higher degree of conservation would identify those sites that are functional in vivo. This method identified 44 candidate PKA substrates, 5 of which had been described. A phosphorylation analysis showed that all of the identified candidates were phosphorylated by PKA and that the likelihood of phosphorylation was strongly correlated with the degree of target site conservation. Finally, as proof of principle, the activity of one particular target, Atg1, a key regulator of autophagy, was shown to be controlled by PKA phosphorylation in vivo. These data therefore suggest that this evolutionary proteomics approach identified a number of PKA substrates that had not been uncovered by other methods. Moreover, these data show how this approach could be generally used to identify the physiologically relevant occurrences of any protein motif identified in a eukaryotic proteome.Ras proteins ͉ sequence conservation ͉ stationary phase P rotein kinases are key components of signal transduction pathways that regulate many aspects of eukaryotic biology (1, 2). The protein kinase gene family is one of the largest in eukaryotic organisms and typically constitutes almost 2% of all protein-encoding genes (3, 4). In general, these enzymes catalyze the transfer of the terminal phosphate from ATP to the hydroxyl group of particular serine, threonine, or tyrosine residues in a defined set of protein targets. This phosphorylation ultimately alters cell physiology by modifying the activities associated with these substrate proteins. A complete understanding of the biology of any protein kinase therefore requires the identification of the particular substrates of this enzyme. Unfortunately, this identification process is often a difficult and labor-intensive task, and, as a result, we generally know few of the physiologically relevant substrates of any protein kinase (5).The cAMP-dependent protein kinase (PKA) has been extensively studied and is one of the best understood members of the protein kinase family (6, 7). In Saccharomyces cerevisiae, PKA is a key regulator of cell growth and is regulated largely by the small GTP-binding Ras proteins (8-10). The two Ras proteins, Ras1 and Ras2, bind to adenylyl cyclase and stimulate the production of cAMP (11,12). This stimulation results in elevated PKA activity and the increased phosphorylation of substrates that are presumably import...
The recruitment model for gene activation presumes that DNA is a platform on which the requisite components of the transcriptional machinery are assembled. In contrast to this idea, we show here that Rap1͞Gcr1͞Gcr2 transcriptional activation in yeast cells occurs through a large anchored protein platform, the Nup84 nuclear pore subcomplex. Surprisingly, Nup84 and associated subcomplex components activate transcription themselves in vivo when fused to a heterologous DNA-binding domain. The Rap1 coactivators Gcr1 and Gcr2 form an important bridge between the yeast nuclear pore complex and the transcriptional machinery. Nucleoporin activation may be a widespread eukaryotic phenomenon, because it was first detected as a consequence of oncogenic rearrangements in acute myeloid leukemia and related syndromes in humans. These chromosomal translocations fuse a homeobox DNA-binding domain to the human homolog (hNup98) of a transcriptionally active component of the yeast Nup84 subcomplex. We conclude that Rap1 target genes are activated by moving to contact compartmentalized nuclear assemblages, rather than through recruitment of the requisite factors to chromatin by means of diffusion. We term this previously undescribed mechanism ''reverse recruitment'' and discuss the possibility that it is a central feature of eukaryotic gene regulation. Reverse recruitment stipulates that activators work by bringing the DNA to an nuclear pore complex-tethered platform of assembled transcriptional machine components.chromatin boundaries ͉ leukemia ͉ silencing ͉ synthetic genetic array ͉ gene regulation A n underlying assumption of both the stepwise and preassembly alternatives (1) of the recruitment model of in vivo gene activation (2-6) is that activators work by bringing the transcriptional machinery to the DNA, i.e., that the machinery itself diffuses relatively freely within the nuclear compartment. We have been studying the repressor͞activator protein Rap1 of Saccharomyces cerevisiae, which recognizes identical motifs in mediating either transcriptional activation (of glycolytic genes and ribosomal protein genes; refs. 7-9) or repression (of silent mating type loci and telomeres; refs. 10-15) and with its coactivators Gcr1 and Gcr2 participates in coordination of growth with cell-cycle progression (16,17). Numerous aspects of Rap1 activation have conformed poorly with the ''free diffusion'' aspect of the recruitment model for transcriptional activation. One such aspect is the presence of an unusually large activation domain that is easily inactivated by means of mutations throughout the N-terminal 280 residues of Gcr1, spanning four distinct hypomutable regions (8,17,18); two of these hypomutable regions overlap with putative transmembrane domains.We report here independent approaches demonstrating that the Rap1͞Gcr1͞Gcr2 activation assemblage (7-9, 19), like its silencing counterpart, is anchored at the nuclear periphery. For example, synthetic genetic array (SGA) analysis identified a robust genetic network that connects the Ra...
SUMMARY Kes1, and other oxysterol binding protein (OSBP) superfamily members, are involved in membrane and lipid trafficking through trans-Golgi network (TGN) and endosomal systems. We demonstrate that Kes1 represents a sterol-regulated antagonist of TGN/endosomal phosphatidylinositol-4-phosphate signaling. This regulation modulates TOR activation by amino acids, and dampens gene expression driven by Gcn4; the primary transcriptional activator of the general amino acid control regulon. Kes1-mediated repression of Gcn4 transcription factor activity is characterized by nonproductive Gcn4 binding to its target sequences, involves TGN/endosome-derived sphingolipid signaling, and requires activity of the cyclin-dependent kinase 8 (CDK8) module of the enigmatic ‘large Mediator’ complex. These data describe a pathway by which Kes1 integrates lipid metabolism with TORC1 signaling and nitrogen sensing.
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