Asg7p-Ste3p inhibition of pheromone signaling: regulation of the zygotic transition to vegetative growth.

The inappropriate expression of the a-factor pheromone receptor (Ste3p) in the MATa cell leads to a striking inhibition of the yeast pheromone response, the result of a functional interaction between Ste3p and some MATa-specific protein. The present work identifies this protein as Asg7p. Normally, expression of Ste3p and Asg7p is limited to distinct haploid mating types, Ste3p to MATalpha cells and Asg7p to MATa cells. Artificial coexpression of the two in the same cell, either a or alpha, leads to dramatic inhibition of the pheromone response. Ste3p-Asg7p coexpression also perturbs the membrane trafficking of Ste3p: Ste3p turnover is slowed, a result of an Asg7p-mediated retardation of the secretory delivery of the newly synthesized receptor to the plasma membrane. However, in the absence of ectopic Ste3p expression, the asg7Delta mutation is without consequence either for pheromone signaling or overall mating efficiency of a cells. Indeed, the sole phenotype that can be assigned to MATa asg7Delta cells is observed following zygotic fusion to its alpha mating partner. Though formed at wild-type efficiency, zygotes from these pairings are morphologically abnormal. The pattern of growth is deranged: emergence of the first mitotic bud is delayed, and, in its place, growth is apparently diverted into a novel structure superficially resembling the polarized mating projection characteristic of haploid cells responding to pheromone. Together these results suggest a mechanism in which, following the zygotic fusion event, Ste3p and Asg7p gain access to one another and together act to repress the pheromone response, promoting the transition of the new diploid cell to vegetative growth.

Ubiquitination of the PEST-like endocytosis signal of the yeast a-factor receptor.

A 58-residue-long, PEST-like sequence within the yeast a-factor receptor (Ste3p) specifies the ubiquitination, endocytosis, and consequent vacuolar degradation of the receptor protein (Roth, A. F., Sullivan, D. M., and Davis, N. G. (1998) J. Cell Biol. 142, 949-961). The present work investigates three lysyl residues that map within this sequence as the potential ubiquitin acceptor sites. Lys --> Arg substitution mutants were tested for effects on both ubiquitination and endocytosis. Results indicate that the three lysines function redundantly; a severe blockade to both ubiquitination and endocytosis is seen only for receptors having all three lysines replaced. Of the three, Lys(432) plays the predominant role; ubiquitination and turnover are significantly impaired for receptors having just the K432R mutation. CNBr fragmentation of the receptor protein, used for the physical mapping of the ubiquitin attachment sites, showed PEST-like sequence lysines to be modified both with single ubiquitin moieties as well with short multi-ubiquitin chains, two or three ubiquitins long. Thus, in addition to being the signal for ubiquitination, the Ste3p PEST-like sequence also provides the site for ubiquitin attachment. To test if this endocytosis signal functions solely for ubiquitination, we have asked if the requirement for the PEST-like sequence in endocytosis might be bypassed through pre-attachment of ubiquitin to the receptor protein. Indeed, Ste3-ubiquitin translational fusions that have a ubiquitin moiety fused to the receptor in place of the PEST-like signal do undergo rapid endocytosis and vacuolar turnover. We conclude that ubiquitin alone, with no required contribution from receptor sequences, provides the sufficient signal for initiating uptake. In addition, our results confirm conclusions originally drawn from studies with the alpha-factor receptor (Terrell, J., Shih, S., Dunn, R., and Hicke, L. (1998) Mol. Cell 1, 193-202), namely that mono-ubiquitin, and not multi-ubiquitin chains provide the primary recognition determinant for uptake. Although mono-ubiquitination suffices, our results indicate that multi-ubiquitination serves to augment the rate of uptake.

A large PEST-like sequence directs the ubiquitination, endocytosis, and vacuolar degradation of the yeast a-factor receptor.

The yeast a-factor receptor (encoded by STE3) is subject to two modes of endocytosis, a ligand-dependent endocytosis as well as a constitutive, ligand-independent mode. Both modes are associated with receptor ubiquitination (Roth, A.F., and N.G. Davis. 1996. J. Cell Biol. 134:661-674) and both depend on sequence elements within the receptor's regulatory, cytoplasmically disposed, COOH-terminal domain (CTD). Here, we concentrate on the Ste3p sequences required for constitutive endocytosis. Constitutive endocytosis is rapid. Receptor is synthesized, delivered to the cell surface, endocytosed, and then delivered to the vacuole where it is degraded, all with a t1/2 of 15 min. Deletion analysis has defined a 36-residue-long sequence mapping near the COOH-terminal end of the Ste3p CTD that is the minimal sequence required for this rapid turnover. Deletions intruding into this interval block or severely slow the rate of endocytic turnover. Moreover, the same 36-residue sequence directs receptor ubiquitination. Mutants deleted for this sequence show undetectable levels of ubiquitination, and mutants having intermediate endocytosis defects show a correlated reduced level of ubiquitination. Not only necessary for ubiquitination and endocytosis, this sequence also is sufficient. When transplanted to a stable cell surface protein, the plasma membrane ATPase Pma1p, the 36-residue STE3 signal directs both ubiquitination of the PMA1-STE3 fusion protein as well as its endocytosis and consequent vacuolar degradation. Alanine scanning mutagenesis across the 36-residue-long interval highlights its overall complexity-no singular sequence motif or signal is found, instead required sequence elements distribute throughout the entire interval. The high proportion of acidic and hydroxylated amino acid residues in this interval suggests a similarity to PEST sequences-a broad class of sequences which have been shown to direct the ubiquitination and subsequent proteosomal degradation of short-lived nuclear and cytoplasmic proteins. A likely possibility, therefore, is that this sequence, responsible for both endocytosis and ubiquitination, may be first and foremost a ubiquitination signal. Finally, we present evidence suggesting that the true signal in the wild-type receptor extends beyond the 36-residue-long sequence defined as a minimal signal to include contiguous PEST-like sequences which extend another 21 residues to the COOH terminus of Ste3p. Together with sequences identified in two other yeast plasma membrane proteins, the STE3 sequence defines a new class of ubiquitination/endocytosis signal.

Ubiquitination of the yeast a-factor receptor.

The a-factor receptor (Ste3p) is one of two pheromone receptors in the yeast Saccharomyces cerevisiae that enable the cell-cell communication of mating. In this report, we show that this receptor is subject to two distinct covalent modifications-phosphorylation and ubiquitination. Phosphorylation, evident on the unstimulated receptor, increases upon challenge by the receptor's ligand, a-factor. We suggest that this phosphorylation likely functions in the adaptive, negative regulation of receptor activity. Removal of phosphorylation by phosphatase treatment uncovered two phosphatase-resistant modifications identified as ubiquitination using a myc-epitope-tagged ubiquitin construct. Ste3p undergoes rapid, ligand-independent turnover that depends on vacuolar proteases and also on transport of the receptor from surface to vacuole (i.e., endocytosis) (Davis, N.G., J.L.Horecka, and G.F. Sprague, Jr., 1993 J. Cell Biol. 122:53-65). An end4 mutation, isolated for its defect in the endocytic uptake of alpha-factor pheromone (Raths, S., J. Rohrer, F. Crausaz, and H. Riezman. 1993. J. Cell Biol. 120:55-65), blocks constitutive endocytosis of the a-factor receptor, yet fails to block ubiquitination of the receptor. In fact, both phosphorylation and ubiquitination of the surfacebound receptor were found to increase, suggesting that these modifications may occur normally while the receptor is at the cell surface. In a mutant strain constructed to allow for depletion of ubiquitin, the level of receptor ubiquitination was found to be substantially decreased. Correlated with this was an impairment of receptor degradative turnover-receptor half-life that is normally approximately 20 min at 30 degrees C was increased to approximately 2 h under these ubiquitin-depletion conditions. Furthermore, surface residency, normally of short duration in wild-type cells (terminated by endocytosis to the vacuole), was found to be prolonged; the majority of the receptor protein remained surface localized fully 2 h after biosynthesis. Thus, the rates of a-factor receptor endocytosis and consequent vacuolar turnover depend on the available level of ubiquitin in the cell. In cells mutant for two E2 activities, i.e., ubc4 delta ubc5 delta cells, the receptor was found to be substantially less ubiquitinated, and in addition, receptor turnover was slowed, suggesting that Ubc4p and Ubc5p may play a role in the recognition of the receptor protein as substrate for the ubiquitin system. In addition to ligand-independent uptake, the a-factor receptor also undergoes a ligand-dependent form of endocytosis (Davis, N.G., J.L. Horecka, and G.F. Sprague, Jr. 1993. J. Cell. Biol. 122:53-65). Concurrent with ligand-dependent uptake, we now show that the receptor undergoes ligand-induced ubiquitination, suggesting that receptor ubiquitination may function in the ligand-dependent endocytosis of the a-factor receptor as well as in its constitutive endocytosis. To account for these findings, we propose a model wherein the covalent attachment of ubiquitin to surface receptor triggers endocytic uptake.

Nuclear magnetic resonance assignments and global fold of a CheY-binding domain in CheA, the chemotaxis-specific kinase of Escherichia coli.

CheA is the histidine autokinase in the Escherichia coli chemotaxis signal transduction pathway responsible for coupling of signals received by transmembrane receptors to the response regulators CheY and CheB. Here NMR spectroscopy is used to study a 14 kDa fragment of CheA, residues 124-257, that binds the response regulator CheY. Backbone atom resonance assignments were obtained by analysis of 3D HNCACB, 3D CBCA(CO)NH, and HNCO spectra, whereas side-chain assignments were obtained primarily by analysis of 3D H(CCO)NH, 3D C(CO)NH, 3D HCCH-TOCSY, and 3D 1H, 15N TOCSY-HSMQC spectra. NOE cross peak patterns and intensities as well as torsion angle restraints were used to determine the secondary structure, and a low-resolution structure was calculated by hybrid distance-geometry simulated annealing methods. The CheA124-257 fragment consists of four antiparallel beta strands and two helices, arranged in an "open-faced beta-sandwich" motif, as well as two unstructured ends that correspond to domain linkers in the full-length protein. The 15N-1H correlation spectrum of 15N-labeled CheA124-257 bound to unlabeled CheY shows specific localized changes that may correspond to a CheY-binding face on CheA.

Heterodimerization of the yeast homeodomain transcriptional regulators alpha 2 and a1: secondary structure determination of the a1 homeodomain and changes produced by alpha 2 interactions.

The homeodomain proteins, a1 and alpha 2, act cooperatively to regulate cell-type specific genes in yeast. The basis of this cooperativity is an interaction between the two proteins, forming a heterodimer that binds DNA tightly and specifically. A fragment containing the homeodomain of a1, a1(66-126), has been studied by NMR spectroscopy to gain secondary structure information and to characterize the changes in a1 upon heterodimerization with alpha 2. Heteronuclear (1H-15N) NMR methods were used to assign backbone resonances of the 61 amino acid fragment. The a1(66-126) secondary structure was determined using NOE connectivities, 3JHN alpha coupling constants and hydrogen exchange kinetic data. NMR data identify three helical segments separated by a loop and a tight turn that are the characteristic structural elements of homeodomain proteins. The a1 fragment was titrated with alpha 2(128-210), the homeodomain-containing fragment of alpha 2, to study changes in a1(66-126) spectra produced by alpha 2 binding. The a1(66-126) protein was labeled with 15N and selectively observed using isotope-edited NMR experiments. NMR spectra of bound a1(66-126) indicate that residues in helix 1, helix 2, and the loop connecting them are directly involved in the binding of the alpha 2 fragment. Relatively minor effects on the resonances from residues in helix 3, the putative DNA-binding helix, were noted upon alpha 2 binding. We have thus located a region of the a1 homeodomain important for specific protein recognition.

Signal transduction in chemotaxis. A propagating conformation change upon phosphorylation of CheY.

The CheY protein from Escherichia coli and Salmonella typhimurium are among the best characterized proteins of the receiver domain family of two component signal transduction systems in bacteria. Phosphorylation of CheY plays a central role in bacterial chemotaxis. However, it is not entirely clear how its state of phosphorylation contributes to its function. Genetic evidence suggests that CheY changes its conformation upon phosphorylation. We present evidence for this conformation change by comparing the NMR 15N-1H correlation spectra of CheY.Mg2+ complex and phospho-CheY in the presence of magnesium. Large changes in chemical shift are used as indicators of chemical changes and probable structural changes in the protein backbone. Our observations suggest that significant structural changes occur in CheY upon phosphorylation and that these changes are distinct from the changes produced by magnesium ion binding. In addition to residues Asn-59 and Gly-65 that are immediately adjacent to the site of phosphorylation at Asp-57, a large number of other residues show significant chemical shift changes as a result of phosphorylation. These include Met-17, Val-21, Asn-23, Gly-39, Met-60, Met-63, Asp-64, Leu-66, Glu-67, Leu-68, Leu-69, Met-85, Val-86, Thr-87, Ala-88, Asn-94, Val-107, Lys-109, Thr-112, Ala-113, Ala-114, and Asn-121. These results appear inconsistent with the recent suggestion that phosphorylation produces the same structural changes as magnesium binding (Bellsolell, L., Prieto, J., Serrano, L., and Coll, M. (1994) J. Mol. Biol. 238, 489-495). We find that some regions change overlap with a genetically defined motor binding face. We therefore propose that the conformation switch modulates the interaction of CheY with its target, the flagellar motor. Other regions also change, possibly reflecting the many different functions of CheY homologues.

Assembly of an MCP receptor, CheW, and kinase CheA complex in the bacterial chemotaxis signal transduction pathway.

We examined the binding interactions of the methylation-dependent chemotaxis receptors Tsr and Tar with the chemotaxis-specific protein kinase CheA and the coupling factor CheW. Receptor directly bound CheW, but receptor-CheA binding was dependent upon the presence of CheW. These observations in combination with our previous identification of a CheW-CheA complex suggest that CheW physically links the kinase to the receptor. The ternary complex of receptor, CheW, and CheA is both kinetically and thermodynamically stable at physiological concentrations. Stability is not significantly altered by changes associated with attractant or repellent binding to the receptor. Such binding greatly modulates the kinase activity of CheA. Our results demonstrate that modulation of the kinase activity does not require association-dissociation of the ternary complex. This suggests that the receptor signal is transduced through conformational changes in the ternary complex rather than through changes in the association of the kinase CheA with receptor and/or CheW.

Mutations that affect control of the methylesterase activity of CheB, a component of the chemotaxis adaptation system in Escherichia coli.

Sensory adaptation by the chemotaxis system of Escherichia coli requires adjustments of the extent of methyl esterification of the chemotaxis receptor proteins. One mechanism utilized by E. coli to make such adjustments is to control the activity of CheB, the enzyme responsible for removing receptor methyl ester groups. Previous work has established the existence of a multicomponent signal transduction pathway that enables the chemotaxis receptor proteins to control the methylesterase activity in response to chemotactic stimuli. We isolated and characterized CheB mutants that do not respond normally to this control mechanism. In intact cells these CheB variants could not be activated in response to negative chemotaxis stimuli. Further characterization indicated that these CheB variants could not be phosphorylated by the chemotaxis protein kinase CheA. Disruption of the mechanism responsible for regulating methylesterase activity was also observed in cells carrying chromosomal deletions of either cheA or cheW as well as in cells expressing mutant versions of CheA that lacked kinase activity. These results provide further support for recent proposals that activation of the methylesterase activity of CheB involves phosphorylation of CheB by CheA. Furthermore, our findings suggest that CheW plays an essential role in enabling the chemotaxis receptor proteins to control the methylesterase activity, possibly by controlling the CheA-CheB phosphotransfer reaction.