Cell polarity: connecting to the cortex.

A GTPase module controls growth-site selection in budding yeast cells. The GDP--GTP exchange factor of this module, Bud5, has now been localized to sites of cell division and shown to interact with a transmembrane protein that marks these sites.

G proteins mediate changes in cell shape by stabilizing the axis of polarity.

Upon exposure to mating pheromone, yeast cells change their form to pear-shaped shmoos. We looked at pheromone-dependent cell shape changes in mutants that are unable to orient growth during mating and unable to choose a bud site. In these double mutants, cell surface growth, secretion sites, cytoskeleton, and pheromone receptors are spread out, explaining why these cells are round. In contrast, polarity establishment proteins localize to discrete sites in these mutants. However, the location of these sites wanders. Thus, these mutants are able to initiate polarized growth but fail to maintain the location of growth sites. Our results demonstrate that stabilization of the growth axis requires positional signaling from either the pheromone receptor or specific bud site selection proteins.

Nucleocytoplasmic shuttling of the Cdc42p exchange factor Cdc24p.

Cdc24p, the GDP/GTP exchange factor for the regulator of actin cytoskeleton Cdc42p, localizes to sites of polarized growth. Here we show that Cdc24p shuttles in and out of the yeast nucleus during vegetative growth. Far1p is necessary and sufficient for nuclear accumulation of Cdc24p, suggesting that its nuclear import occurs via an association with Far1p. Nuclear export is triggered either by entry into the cell cycle or by mating pheromone. As Far1p is degraded upon entry into the cell cycle, cell cycle-dependent export of Cdc24p occurs in the absence of Far1p, whereas during mating similar export kinetics indicate that a Cdc24p-Far1p complex is exported. Our results suggest that the nucleus serves as a store of preformed Cdc24p-Far1p complex which is required for chemotropism.

A Cdc24p-Far1p-Gbetagamma protein complex required for yeast orientation during mating.

Oriented cell growth requires the specification of a site for polarized growth and subsequent orientation of the cytoskeleton towards this site. During mating, haploid Saccharomyces cerevisiae cells orient their growth in response to a pheromone gradient overriding an internal landmark for polarized growth, the bud site. This response requires Cdc24p, Far1p, and a heterotrimeric G-protein. Here we show that a two- hybrid interaction between Cdc24p and Gbeta requires Far1p but not pheromone-dependent MAP-kinase signaling, indicating Far1p has a role in regulating the association of Cdc24p and Gbeta. Binding experiments demonstrate that Cdc24p, Far1p, and Gbeta form a complex in which pairwise interactions can occur in the absence of the third protein. Cdc24p localizes to sites of polarized growth suggesting that this complex is localized. In the absence of CDC24-FAR1-mediated chemotropism, a bud site selection protein, Bud1p/Rsr1p, is essential for morphological changes in response to pheromone. These results suggest that formation of a Cdc24p-Far1p-Gbetagamma complex functions as a landmark for orientation of the cytoskeleton during growth towards an external signal.

Responding to attraction: chemotaxis and chemotropism in Dictyostelium and yeast.

Polarized growth in response to external signals is essential for both the internal organization of cells and generation of complex multicellular structures during development. Oriented growth or movement requires specific detection of an external cue, reorganization of the cytoskeleton and subsequent growth or movement. Genetic approaches in both the budding yeast Saccharomyces cerevisiae and the social amoeba Dictyostelium discoideum have shed light on the molecular and cellular aspects of growth or movement towards an external signal. This review discusses the mechanisms and signalling pathways that enable yeast and Dictyostelium cells to translate external signals into directed growth and movement, respectively.

A GTP-exchange factor required for cell orientation.

The Rho-family of GTPases and their regulators are essential for cytoskeletal reorganization and transcriptional activation in response to extracellular signals. Little is known about what links these molecules to membrane receptors. In the budding yeast Saccharomyces cerevisiae, haploid cells respond to mating pheromone through a G-protein-coupled receptor and the betagamma subunit of the G protein, resulting in arrest of the cell cycle, transcriptional activation, and polarized growth towards a mating partner. The Rho-family GTPase Cdc42 and its exchange factor Cdc24 have been implicated in the mating process, but their specific role is unknown. Here we report the identification of cdc24 alleles that do not affect vegetative growth but drastically reduce the ability of yeast cells to mate. When exposed to mating pheromone, these mutants arrest growth, activate transcription, and undergo characteristic morphological and actin-cytoskeleton polarization. However, the mutants are unable to orient towards a pheromone gradient, and instead position their mating projection adjacent to their previous bud site. The mutants are specifically defective in the binding of Cdc24 to the G-protein betagamma subunit. Our results demonstrate that the association of an exchange factor and the betagamma subunit of a hetero-trimeric G protein links receptor-mediated activation to oriented cell growth.

A small conserved domain in the yeast Spa2p is necessary and sufficient for its polarized localization.

SPA2 encodes a yeast protein that is one of the first proteins to localize to sites of polarized growth, such as the shmoo tip and the incipient bud. The dynamics and requirements for Spa2p localization in living cells are examined using Spa2p green fluorescent protein fusions. Spa2p localizes to one edge of unbudded cells and subsequently is observable in the bud tip. Finally, during cytokinesis Spa2p is present as a ring at the mother-daughter bud neck. The bud emergence mutants bem1 and bem2 and mutants defective in the septins do not affect Spa2p localization to the bud tip. Strikingly, a small domain of Spa2p comprised of 150 amino acids is necessary and sufficient for localization to sites of polarized growth. This localization domain and the amino terminus of Spa2p are essential for its function in mating. Searching the yeast genome database revealed a previously uncharacterized protein which we name, Sph1p (a2p omolog), with significant homology to the localization domain and amino terminus of Spa2p. This protein also localizes to sites of polarized growth in budding and mating cells. SPH1, which is similar to SPA2, is required for bipolar budding and plays a role in shmoo formation. Overexpression of either Spa2p or Sph1p can block the localization of either protein fused to green fluorescent protein, suggesting that both Spa2p and Sph1p bind to and are localized by the same component. The identification of a 150-amino acid domain necessary and sufficient for localization of Spa2p to sites of polarized growth and the existence of this domain in another yeast protein Sph1p suggest that the early localization of these proteins may be mediated by a receptor that recognizes this small domain.

The fate of the carboxyl oxygens during D-proline reduction by clostridial proline reductase.

D-Proline is converted to 5-amino valeric acid by D-proline reductase. This conversion involves the reductive cleavage of the alpha-carbon-nitrogen bond. We have examined the fate of the carboxyl oxygen atoms during conversion of D-proline to delta-NH2-valeric acid. 18O atoms from the carboxyl group of D-proline are not lost during conversion to product. In contrast, in the conversion of glycine to acetyl phosphate by glycine reductase a carboxyl oxygen atom is lost to solvent. An intermediate acyl-enzyme is found during the reduction of glycine. We conclude that the reduction of proline proceeds without the formation of an acyl enzyme intermediate.

SecD and SecF are required for the proton electrochemical gradient stimulation of preprotein translocation.

Mutations in secD and secF show impaired protein translocation across the inner membrane of Escherichia coli. We investigated the effect of SecD and SecF (SecD/F) depletion on preprotein translocation into inverted inner membrane vesicles (IMVs). Both IMVs and cells which were depleted of SecD/F were defective in their ability to maintain a proton electrochemical gradient. The translocation of pre-maltose binding protein (preMBP), which is strongly delta microH+ dependent, showed a 5-fold decreased rate with IMVs lacking SecD/F. In contrast, proteolytic processing of preMBP to MBP by leader peptidase was similar in IMVs containing and lacking SecD/F, consistent with earlier findings that only ATP-dependent translocation is required for the initiation of translocation. In the absence of a delta microH+, with ATP as the sole energy source, preMBP translocation into IMVs which contained or were depleted of SecD/F was identical. Translocation of the precursor of outer membrane protein A (proOmpA) in the presence of subsaturating ATP also required a generated delta microH+ and, under these conditions, proOmpA translocation required SecD/F. With saturating concentrations of ATP, where delta microH+ has little effect on in vitro proOmpA translocation, SecD/F also had little effect on translocation. These results explain why SecD/F effects are precursor protein dependent in vitro.

Translocation can drive the unfolding of a preprotein domain.

Precursor proteins are believed to have secondary and tertiary structure prior to translocation across the Escherichia coli plasma membrane. We now find that preprotein unfolding during translocation can be driven by the translocation event itself. At certain stages, translocation and unfolding can occur without exogenous energy input. To examine this unfolding reaction, we have prepared proOmpA-Dhfr, a fusion protein of the well studied cytosolic enzyme dihydrofolate reductase (Dhfr) connected to the C-terminus of proOmpA, the precursor form of outer membrane protein A. At an intermediate stage of its in vitro translocation, the N-terminal proOmpA domain has crossed the membrane while the folded Dhfr portion, stabilized by its ligands NADPH and methotrexate, has not. When the ligands are removed from this intermediate, translocation occurs by a two-step process. First, 20-30 amino acid residues of the fusion protein translocate concomitant with unfolding of the Dhfr domain. This reaction requires neither ATP, delta mu H+ nor the SecA subunit of translocase. Strikingly, this translocation accelerates the net unfolding of the Dhfr domain. In a second step, SecA and ATP hydrolysis drive the rapid completion of translocation. Thus energy derived from translocation can drive the unfolding of a substantial protein domain.

The role of the mature domain of proOmpA in the translocation ATPase reaction.

The export of proOmpA, the precursor of outer membrane protein A from Escherichia coli, requires preprotein translocase, which is comprised of SecA, SecY/E, and acidic phospholipids. Previous studies of proOmpA translocation intermediates (Schiebel, E., Driessen, A. J. M., Hartl, F.-U., and Wickner, W. (1991) Cell 64, 927-939) suggested that the "slippage" of the translocating polypeptide chain and the high level of ATP hydrolysis, characteristic of the "translocation ATPase," were part of a futile cycle. To examine the role of the mature domain of proOmpA in its translocation-dependent ATP hydrolysis, we used chemical cleavage to generate NH2-terminal fragments of this preprotein. Each fragment contained the 21-residue leader region and either 53 or 228 residues of the mature domain (preproteins P74 and P249, respectively). As observed with full-length proOmpA, the translocation of each fragment requires ATP and both the SecA and SecY/E domains of translocase and is stimulated by the transmembrane proton electrochemical gradient. The apparent maximal velocities of P74 and proOmpA translocation are similar. While the translocation of P74 and of proOmpA show the same apparent Km for ATP, far less ATP is hydrolyzed during the translocation of P74. Thus, the mature carboxyl-terminal domain of proOmpA has a major role in supporting the translocation ATPase.

Mechanism of action of clostridial glycine reductase: isolation and characterization of a covalent acetyl enzyme intermediate.

Clostridial glycine reductase consists of proteins A, B, and C and catalyzes the reaction glycine + Pi + 2e(-)----acetyl phosphate + NH4+. Evidence was previously obtained that is consistent with the involvement of an acyl enzyme intermediate in this reaction. We now demonstrate that protein C catalyzes exchange of [32P]Pi into acetyl phosphate, providing additional support for an acetyl enzyme intermediate on protein C. Furthermore, we have isolated acetyl protein C and shown that it is qualitatively catalytically competent. Acetyl protein C can be obtained through the forward reaction from protein C and Se-(carboxymethyl)selenocysteine-protein A, which is generated by the reaction of glycine with proteins A and B [Arkowitz, R. A., & Abeles, R. H. (1990) J. Am. Chem. Soc. 112, 870-872]. Acetyl protein C can also be generated through the reverse reaction by the addition of acetyl phosphate to protein C. Both procedures lead to the same acetyl enzyme. The acetyl enzyme reacts with Pi to give acetyl phosphate. When [14C]acetyl protein C is denaturated with TCA and redissolved with urea, radioactivity remained associated with the protein. At pH 11.5 radioactivity was released with t1/2 = 57 min, comparable to the hydrolysis rate of thioesters. Exposure of 4 N neutralized NH2OH resulted in the complete release of radioactivity. Treatment with KBH4 removes all the radioactivity associated with protein C, resulting in the formation of [14C]ethanol. We conclude that a thiol group on protein C is acetylated. Proteins A and C together catalyze the exchange of tritium atoms from [3H]H2O into acetyl phosphate.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of acetyl phosphate as the product of clostridial glycine reductase: Evidence for an acyl enzyme intermediate.

It has been reported [Tanaka, H., & Stadtman, T. C. (1979) J. Biol. Chem. 254, 447-452] that glycine reductase from Clostridium sticklandii catalyzes the reaction glycine + ADP + P(i) + 2(e)- - acetate + ATP + NH(4)+. Glycine reductase consists of three proteins, designated A, B, and C. Only A has been purified to homogeneity. A dithiol serves as an electron donor. We find that ADP is not essential for the reaction and that in its absence acetyl phosphate is formed. Upon further purification of components B and C, an acetate kinase activity can be separated from both proteins. This observation establishes that acetate kinase activity is not an intrinsic property of glycine reductase, and therefore the reaction catalyzed by glycine reductase is glycine + P(i) + 2(e)- - acetyl phosphate + NH(4)+. Experiments with [(14)C]glycine and unlabeled acetate show that free acetate is not a precursor of acetyl phosphate. When glycine labeled with l8(O) is converted to product, l8(O) is lost. The l 8 (O) content of unreacted glycine remains unchanged after approximately 50% is converted to product. We propose that an acyl enzyme, most probably an acetyl enzyme,is an intermediate in the reaction and that the acetyl enzyme reacts with P(i) to form acetyl phosphate. A mechanism is proposed for the formation of the acetyl enzyme.

Decomposition of hydroxylamine by hemoglobin.

The reaction between hydroxylamine (NH2OH) and human hemoglobin (Hb) at pH 6-8 and the reaction between NH2OH and methemoglobin (Hb+) chiefly at pH 7 were studied under anaerobic conditions at 25 degrees C. In presence of cyanide, which was used to trap Hb+, Hb was oxidized by NH2OH to methemoglobin cyanide with production of about 0.5 mol NH+4/mol of heme oxidized at pH 7. The conversion of Hb to Hb+ was first order in [Hb] (or nearly so) but the pseudo-first-order rate constant was not strictly proportional to [NH2OH]. Thus, the apparent second-order rate constant at pH 7 decreased from about 30 M-1 X s-1 to a limiting value of 11.3 M-1 X s-1 with increasing [NH2OH]. The rate of Hb oxidation was not much affected by cyanide, whereas there was no reaction between NH2OH and carbonmonoxyhemoglobin (HbCO). The pseudo-first-order rate constant for Hb oxidation at 500 microM NH2OH increased from about 0.008 s-1 at pH 6 to 0.02 s-1 at pH 8. The oxidation of Hb by NH2OH terminated prematurely at 75-90% completion at pH 7 and at 30-35% completion at pH 8. Data on the premature termination of reaction fit the titration curve for a group with pK = 7.5-7.7. NH2OH was decomposed by Hb+ to N2, NH+4, and a small amount of N2O in what appears to be a dismutation reaction. Nitrite and hydrazine were not detected, and N2 and NH+4 were produced in nearly equimolar amounts. The dismutation reaction was first order in [Hb+] and [NH2OH] only at low concentrations of reactants and was cleanly inhibited by cyanide. The spectrum of Hb+ remained unchanged during the reaction, except for the gradual formation of some choleglobin-like (green) pigment, whereas in the presence of CO, HbCO was formed. Kinetics are consistent with the view advanced previously by J. S. Colter and J. H. Quastel [1950) Arch. Biochem. 27, 368-389) that the decomposition of NH2OH proceeds by a mechanism involving a Hb/Hb+ cycle (reactions [1] and [2]) in which Hb is oxidized to Hb+ by NH2OH.