Protein N-terminal methionine excision.

N-terminal methionine excision (NME) is the major proteolytic pathway responsible for the diversity of N-terminal amino acids in proteins. Dedicated NME components have been identified in all organisms, in all compartments in which protein synthesis occurs: cytoplasm, plastids and mitochondria. Recent studies have revealed that NME is regulated at various levels and plays an important role in controlling protein turnover. NME is essential in Eubacteria and lower eukaryotes and is the target of many natural and synthetic inhibitors. Such inhibitors have considerable potential for use in the treatment of various human diseases, from cancer to bacterial and parasitic infections.

Organellar peptide deformylases: universality of the N-terminal methionine cleavage mechanism.

Most mature proteins do not retain their initial N-terminal amino acid (methionine in the cytosol and N-formyl methionine in the organelles). Recent studies have shown that dedicated machinery is involved in this process in plants. In addition to cytosolic and organelle-targeted methionine aminopeptidases, organellar peptide deformylases have been identified. Here, we attempt to answer questions about the mechanism, specificity and significance of N-terminal methionine cleavage in plant organelles. It seems to be universal because orthologues of plant deformylases are found in most living organisms.

Distinctive features of the two classes of eukaryotic peptide deformylases.

Peptide deformylases (PDFs) are essential enzymes of the N-terminal protein processing pathway of eubacteria. The recent discovery of two types of PDFs in higher plants, PDF1A and PDF1B, and the detection of PDF1A in humans, have raised questions concerning the importance of deformylation in eukaryotes. Here, we have characterized fully in vitro and compared the properties of the two classes of eukaryotic PDFs, PDF1A and PDF1B, using the PDFs from Arabidopsis thaliana and Lycopersicon esculentum. We have shown that the PDFs of a given class (1A or 1B) all display similar features, independently of their origin. We also observed similar specificity of all plant PDFs for natural substrate peptides, but identified a number of biochemical differences between the two classes (1A or 1B). The main difference lies at the level of the bound cofactor, iron for PDF1B-like bacterial PDFs, and zinc for PDF1A. The nature of the metal cation has important consequences concerning the relative sensitivity to oxygen of the two plant PDFs. Investigation of the specificity of these enzymes with unusual substrates revealed additional differences between the two types of PDFs, enabling us to identify specific inhibitors with a lower affinity against PDF1As. However, the two plant PDFs were inhibited equally strongly in vitro by actinonin, an antibiotic that specifically acts on bacterial PDFs. Uptake of actinonin by A. thaliana seedlings was used to investigate the function of PDFs in the plant. Because it induces an albino phenotype, we conclude that deformylation is likely to play an essential role in the chloroplast.

Differential actions of p60c-Src and Lck kinases on the Ras regulators p120-GAP and GDP/GTP exchange factor CDC25Mm.

It is known that the human Ras GTPase activating protein (GAP) p120-GAP can be phosphorylated by different members of the Src kinase family and recently phosphorylation of the GDP/GTP exchange factor (GEF) CDC25Mm/GRF1 by proteins of the Src kinase family has been revealed in vivo [Kiyono, M., Kaziro, Y. & Satoh, T. (2000) J. Biol. Chem. 275, 5441-5446]. As it still remains unclear how these phosphorylations can influence the Ras pathway we have analyzed the ability of p60c-Src and Lck to phosphorylate these two Ras regulators and have compared the activity of the phosphorylated and unphosphorylated forms. Both kinases were found to phosphorylate full-length or truncated forms of GAP and GEF. The use of the catalytic domain of p60c-Src showed that its SH3/SH2 domains are not required for the interaction and the phosphorylation of both regulators. Remarkably, the phosphorylations by the two kinases were accompanied by different functional effects. The phosphorylation of p120-GAP by p60c-Src inhibited its ability to stimulate the Ha-Ras-GTPase activity, whereas phosphorylation by Lck did not display any effect. A different picture became evident with CDC25Mm; phosphorylation by Lck increased its capacity to stimulate the GDP/GTP exchange on Ha-Ras, whereas its phosphorylation by p60c-Src was ineffective. Our results suggest that phosphorylation by p60c-Src and Lck is a selective process that can modulate the activity of p120-GAP and CDC25Mm towards Ras proteins.

The Ras GDP/GTP cycle is regulated by oxidizing agents at the level of Ras regulators and effectors.

Reactive oxygen species (ROS) have been found to play important roles in regulating cellular functions. Their action in vivo has been related to specific effects on signal transduction pathways, such as Ras pathway. In order to characterize which elements of Ras pathway are affected by ROS, we have analyzed the action of different oxidizing agents on the ability of GTPase activating protein GAP and nucleotide exchange factor GEF to enhance the intrinsic activities of Ras. The action of these agents on the binding between H-Ras and its effector c-Raf-1 was also investigated. No effects were observed on the intrinsic activities of H-Ras or Ras2p. On the other hand, reversible inhibitions of GEF and GAP actions on Ras were found, whose extent was dependent on the agent used. As tested with the scintillation proximity assay, these agents also inhibited the binding of c-Raf-1 to H-Ras. Our data reveal new potential targets for the action of ROS on Ras pathway and suggest that they can influence the Ras activation state indirectly via regulators and effectors.

Peptide deformylase as an emerging target for antiparasitic agents.

Peptide deformylases (PDFs) constitute a growing family of hydrolytic enzymes previously believed to be unique to Eubacteria. Recent data from our laboratory have demonstrated that PDF orthologues are present in many eukaryotes, including several parasites. In this report we aim to explain why PDF could be considered to be a potent target for human and veterinary antiparasitic treatments.

Identification of eukaryotic peptide deformylases reveals universality of N-terminal protein processing mechanisms.

The N-terminal protein processing pathway is an essential mechanism found in all organisms. However, it is widely believed that deformylase, a key enzyme involved in this process in bacteria, does not exist in eukaryotes, thus making it a target for antibacterial agents such as actinonin. In an attempt to define this process in higher eukaryotes we have used Arabidopsis thaliana as a model organism. Two deformylase cDNAs, the first identified in any eukaryotic system, and six distinct methionine aminopeptidase cDNAs were cloned. The corresponding proteins were characterized in vivo and in vitro. Methionine aminopeptidases were found in the cytoplasm and in the organelles, while deformylases were localized in the organelles only. Our work shows that higher plants have a much more complex machinery for methionine removal than previously suspected. We were also able to identify deformylase homologues from several animals and clone the corresponding cDNA from human cells. Our data provide the first evidence that lower and higher eukaryotes, as well as bacteria, share a similar N-terminal protein processing machinery, indicating universality of this system.

Peptide deformylase as a target for new generation, broad spectrum antimicrobial agents.

Peptide deformylase was discovered 30 years ago, but as a result of its unusually unstable activity it was not fully characterized until very recently. The aim of this paper is to review the many recent data concerning this enzyme and to try to assess its potential as a target for future antimicrobial drugs.

Raf-1 is involved in the regulation of the interaction between guanine nucleotide exchange factor and Ha-ras. Evidences for a function of Raf-1 and phosphatidylinositol 3-kinase upstream to Ras.

The observation that activated c-Ha-Ras p21 interacts with diverse protein ligands suggests the existence of mechanisms that regulate multiple interactions with Ras. This work studies the influence of the Ras effector c-Raf-1 on the action of guanine nucleotide exchange factors (GEFs) on Ha-Ras in vitro. Purified GEFs (the catalytic domain of yeast Sdc25p and the full-length and catalytic domain of mouse CDC25Mm) and the Ras binding domains (RBDs) of Raf-1 (Raf (1-149) and Raf (51-131)) were used. Our results show that not only the intrinsic GTP/GTP exchange on Ha-Ras but also the GEF-stimulated exchange is inhibited in a concentration-dependent manner by the RBDs of Raf. Conversely, the scintillation proximity assay, which monitors the effect of GEF on the Ras.Raf complex, showed that the binding of Raf and GEF to Ha-Ras.GTP is mutually exclusive. The various GEFs used yielded comparable results. It is noteworthy that under more physiological conditions mimicking the cellular GDP/GTP ratio, Raf enhances the GEF-stimulated GDP/GTP exchange on Ha-Ras, in agreement with the sequestration of Ras.GTP by Raf. Consistent with our results, the GEF-stimulated exchange of Ha-Ras.GTP was also inhibited by another effector of Ras, the RBD (amino acid residues 133-314) of phosphatidylinositol 3-kinase p110alpha. Our data show that Raf-1 and phosphatidylinositol 3-kinase can influence the upstream activation of Ha-Ras. The interference between Ras effectors and GEF could be a regulatory mechanism to promote the activity of Ha-Ras in the cell.

A new function of p120-GTPase-activating protein. Prevention of the guanine nucleotide exchange factor-stimulated nucleotide exchange on the active form of Ha-ras p21.

This work studies the coordination of the action of GTPase-activating protein (GAP) and guanine nucleotide exchange factor (GEF) on activated human c-Ha-Ras p21. Purified human p120-GAP was obtained with a new efficient procedure. To distinguish the GTPase-activating effect of p120-GAP from other effects dependent on the interaction with activated Ha-Ras, the nonhydrolyzable GTP analogue guanosine 5'-O-(thiotriphosphate) (GTPgammaS) was used. The results showed that the GTPgammaS/GTPgammaS exchange enhanced by the C-terminal catalytic domain of the yeast GEF Sdc25p (C-Sdc25p) is prevented by p120-GAP. This effect is strictly specific for the activated form of Ha-Ras, the target of GAP; no effect on Ha-Ras.GDP was detectable. The GAP catalytic domain also inhibited C-Sdc25p but to a lower extent. The interfering effect by p120-GAP was also evident in a homologous mammalian system, using full-length mouse RasGEF, its C-terminal half-molecule, or C-terminal catalytic domain. As a consequence of this inhibition, presence of p120-GAP enhanced the regeneration of Ha-Ras.GTPgammaS by GEF at a GDP:GTPgammaS ratio mimicking the in vivo GDP:GTP ratio. Our work describes a novel function of p120-GAP and suggests a mechanism by which GAP protects Ha-Ras.GTP in vivo against unproductive exchanges. This constrain is likely involved in the regulation of the physiological GDP/GTP cycle of Ras and in the action of p120-GAP as downstream effector of Ras. Helix alpha3 is proposed as a Ras element playing a key-role in the interference between GAP and GEF on Ras.

Anion effects on vesicle acidification in Dictyostelium.

Chloride ions stimulated the ATP-dependent formation of a proton gradient in vesicles derived from amoebae of the cellular slime mould, D. discoideum, and reduced the formation of a membrane potential, inhibited rather than stimulated the formation of the proton gradient. Since bicarbonate ions did not inhibit H(+)-ATPase activity we conclude that they enter the vesicles and combine with translocated protons. This finding is consistent with the suggestion that the membranes of the light vesicle fraction are fragments of contractile vacuole complexes, and that these organelles increase their osmotic activity by taking up bicarbonate ions and protons from the cytoplasm, and then release water and carbonic acid into the extracellular milieu.