Post-translational processing of Schizosaccharomyces pombe YPT5 protein. In vitro and in vivo analysis of processing mutants

The small GTPase Rab5 homologue Ypt5 regulates cell morphology, sexual development, ion-stress response and vacuolar formation in fission yeast

Inner-membrane transport is critical to cell function. Rab family GTPases play an important role in vesicle transport. In mammalian cells, Rab5 is reported to be involved in the regulation of endosome formation, phagocytosis and chromosome alignment. Here, we examined the role of the fission yeast Rab5 homologue Ypt5 using a point mutant allele. Mutant cells displayed abnormal cell morphology, mating, sporulation, endocytosis, vacuole fusion and responses to ion stress. Our data strongly suggest that fission yeast Rab5 is involved in the regulation of various types of cellular functions.

Genetic control of cellular quiescence in S. pombe

Transition from proliferation to quiescence brings about extensive changes in cellular behavior and structure. However, the genes that are crucial for establishing and/or maintaining quiescence are largely unknown. The fission yeast Schizosaccharomyces pombe is an excellent model in which to study this problem, because it becomes quiescent under nitrogen starvation. Here, we characterize 610 temperature-sensitive mutants, and identify 33 genes that are required for entry into and maintenance of quiescence. These genes cover a broad range of cellular functions in the cytoplasm, membrane and nucleus. They encode proteins for stress-responsive and cell-cycle kinase signaling pathways, for actin-bound and osmo-controlling endosome formation, for RNA transcription, splicing and ribosome biogenesis, for chromatin silencing, for biosynthesis of lipids and ATP, for cell-wall and membrane morphogenesis, and for protein trafficking and vesicle fusion. We specifically highlight Fcp1, a CTD phosphatase of RNA polymerase II, which differentially affects the transcription of genes that are involved in quiescence and proliferation. We propose that the transcriptional role of Fcp1 is central in differentiating quiescence from proliferation.

Metabolic labeling of prenyl and carboxyl-methyl groups

This unit provides protocols for prenylation and carboxy-methylation of proteins in cultured cells. These modifications often accompany fatty acid acylation. Cultured cells can be labeled biosynthetically using radiolabeled mevalonate, a precursor, to label intermediates that are incorporated as prenoids--e.g., farnesyl and geranylgeranyl. Carboxy-methylation often accompanies prenylation. The methyl group can be labeled using [(3)H-methyl]methionine.

Membrane targeting of Rab GTPases is influenced by the prenylation motif

Rab GTPases are regulators of membrane traffic. Rabs specifically associate with target membranes via the attachment of (usually) two geranylgeranyl groups in a reaction involving Rab escort protein and Rab geranylgeranyl transferase. In contrast, related GTPases are singly prenylated by CAAX prenyl transferases. We report that di-geranylgeranyl modification is important for targeting of Rab5a and Rab27a to endosomes and melanosomes, respectively. Transient expression of EGFP-Rab5 mutants containing two prenylatable cysteines (CGC, CC, CCQNI, and CCA) in HeLa cells did not affect endosomal targeting or function, whereas mono-cysteine mutants (CSLG, CVLL, or CVIM) were mistargeted to the endoplasmic reticulum (ER) and were nonfunctional. Similarly, Rab27aCVLL mutant is also mistargeted to the ER and transgenic expression on a Rab27a null background (Rab27aash) did not rescue the coat color phenotype, suggesting that Rab27aCVLL is not functional in vivo. CAAX prenyl transferase inhibition and temperature-shift experiments further suggest that Rabs, singly or doubly modified are recruited to membranes via a Rab escort protein/Rab geranylgeranyl transferase-dependent mechanism that is distinct from the insertion of CAAX-containing GTPases. Finally, we show that both singly and doubly modified Rabs are extracted from membranes by RabGDIalpha and propose that the mistargeting of Rabs to the ER results from loss of targeting information.

Analysis of protein prenylation and carboxyl-methylation

This unit describes methods for analysis of prenylation and the carboxyl-methylation that often accompanies it. The two prenoid groups that have been found attached to proteins--farnesyl (C15) and geranylgeranyl (C20)--are both derived from intermediates in the isoprenoid biosynthetic pathway that utilizes mevalonic acid. In the protocols described here, radiolabeled mevalonate is used to label these intermediates in either intact cells or in vitro; the labeled intermediates then become incorporated into proteins. Alternatively, the preformed radioactive prenyl diphosphates can be used for in vitro translations, as described here. Carboxyl-methylation of C-terminal prenylated cysteine residues often occurs subsequent to prenylation. Methods are given for radiolabeling of the methyl group with [(3)H-methyl]methionine, that is converted intracellularly into S-adenosylmethionine, and for radiolabeling with preformed S-adenosyl[(3)H]methionine.

Isoprenylcysteine carboxyl methyltransferase deficiency in mice

After isoprenylation, Ras and other CAAX proteins undergo endoproteolytic processing by Rce1 and methylation of the isoprenylcysteine by Icmt (isoprenylcysteine carboxyl methyltransferase). We reported previously that Rce1-deficient mice died during late gestation or soon after birth. We hypothesized that Icmt deficiency might cause a milder phenotype, in part because of reports suggesting the existence of more than one activity for methylating isoprenylated proteins. To address this hypothesis and also to address the issue of other methyltransferase activities, we generated Icmt-deficient mice. Contrary to our expectation, Icmt deficiency caused a more severe phenotype than Rce1 deficiency, with virtually all of the knockout embryos (Icmt-/-) dying by mid-gestation. An analysis of chimeric mice produced from Icmt-/- embryonic stem cells showed that the Icmt-/- cells retained the capacity to contribute to some tissues (e.g. skeletal muscle) but not to others (e.g. brain). Lysates from Icmt-/- embryos lacked the ability to methylate either recombinant K-Ras or small molecule substrates (e.g. N-acetyl-S-geranylgeranyl-l-cysteine). In addition, Icmt-/- cells lacked the ability to methylate Rab proteins. Thus, Icmt appears to be the only enzyme participating in the carboxyl methylation of isoprenylated proteins.

Interactions of (-)-ilimaquinone with methylation enzymes: implications for vesicular-mediated secretion

BACKGROUND

The marine sponge metabolite (-)-ilimaquinone has antimicrobial, anti-HIV, anti-inflammatory and antimitotic activities, inhibits the cytotoxicity of ricin and diptheria toxin, and selectively fragments the Golgi apparatus. The range of activities demonstrated by this natural product provides a unique opportunity for studying these cellular processes.

RESULTS

Affinity chromatography experiments show that (-)-ilimaquinone interacts with enzymes of the activated methyl cycle: S-adenosylmethionine synthetase, S-adenosylhomocysteinase and methyl transferases. Known inhibitors of these enzymes were found to block vesicle-mediated secretion in a manner similar to (-)-ilimaquinone. Moreover, the antisecretory effects of (-)-ilimaquinone and inhibitors of methylation chemistry, but not brefeldin A, could be reversed in the presence of the cellular methylating agent S-adenosylmethionine. Of the enzymes examined in the activated methyl cycle, S-adenosylhomocysteinase was specifically inhibited by (-)-ilimaquinone. Consistent with these observations, (-)-ilimaquinone was shown to obstruct new methylation events in adrenocorticotrophic hormone (ACTH)-secreting pituitary cells.

CONCLUSIONS

(-)-ilimaquinone inhibits cellular methylations through its interactions with S-adenosylhomocysteinase. Furthermore, these studies indicate that the inhibition of secretion by ilimaquinone is the result of the natural product's antimethylation activity. It is likely that the ability to fragment the Golgi apparatus, as well as other activities, are also related to ilimaquinone's influence on methylation chemistry.

A Rab1 homologue with a novel isoprenylation signal provides insight into the secretory pathway of Theileria parva

As a first step in developing compartment-specific markers for protein trafficking within Theileria parva, we have isolated cDNAs encoding homologues of the small GTP binding proteins Rab1 and Rab4. The T. parva homologue of Rab1 (TpRab1), a protein which regulates vesicular transport between the endoplasmic reticulum and cis golgi in other organisms, was unusual in that it contained a unique 17 amino acid C-terminal extension. The C-terminal motif sequence KCT (XCX) contrasted with the CXC or XCC motifs which act as as signals for isoprenylation by geranylgeranyl in most Rab proteins, including all known Rab1 homologues, in containing only a single cysteine. [C14]mevalonic acid lactone and [H3]geranylgeranyl pyrophosphate were specifically incorporated into recombinant TpRab1 in vitro, demonstrating that the novel motif was functional for isoprenylation. Recombinant TpRab1 bound radiolabeled GTP, and this binding was inhibited by excess unlabeled GTP and GDP and also partially by ATP. The TpRab1 gene contained four short (34-67 bp) introns with a distinct pattern of occurrence within the protein sequence as compared to the introns of other lower eukaryote Rab1 genes. Immunofluorescence microscopy using antiserum specific for the novel C-terminal peptide in combination with labelling of cells using the nucleic acid-staining dye DAPI, indicated that TpRab1 was located in the vicinity of the schizont nucleus within the infected lymphocyte.

Acylation of Escherichia coli hemolysin: a unique protein lipidation mechanism underlying toxin function

The pore-forming hemolysin (HlyA) of Escherichia coli represents a unique class of bacterial toxins that require a posttranslational modification for activity. The inactive protoxin pro-HlyA is activated intracellularly by amide linkage of fatty acids to two internal lysine residues 126 amino acids apart, directed by the cosynthesized HlyC protein with acyl carrier protein as the fatty acid donor. This action distinguishes HlyC from all bacterial acyltransferases such as the lipid A, lux-specific, and nodulation acyltransferases, and from eukaryotic transferases such as N-myristoyl transferases, prenyltransferases, and thioester palmitoyltransferases. Most lipids directly attached to proteins may be classed as N-terminal amide-linked and internal ester-linked acyl groups and C-terminal ether-linked isoprenoid groups. The acylation of HlyA and related toxins does not equate to these but does appear related to a small number of eukaryotic proteins that include inflammatory cytokines and mitogenic and cholinergic receptors. While the location and structure of lipid moieties on proteins vary, there are common effects on membrane affinity and/or protein-protein interactions. Despite being acylated at two residues, HlyA does not possess a "double-anchor" motif and does not have an electrostatic switch, although its dependence on calcium binding for activity suggests that the calcium-myristoyl switch may have relevance. The acyl chains on HlyA may provide anchorage points onto the surface of the host cell lipid bilayer. These could then enhance protein-protein interactions either between HlyA and components of a host signal transduction pathway to influence cytokine production or between HlyA monomers to bring about oligomerization during pore formation.

Chemical biology of protein isoprenylation/methylation

Isoprenylation/methylation is an important dual hydrophobic post-translational modification which occurs at or near a carboxyl terminal cysteine residue. All known G proteins are modified in this way, making the pathway of central interest for an understanding of signal transduction. In this review, aspects of the molecular enzymology of isoprenylation/methylation are reviewed. The functional significance of these modifications is discussed, with special reference to the signal transducing G proteins. Of further interest is the possible regulatory role of methylation, since this step is the only reversible one in the pathway. The biochemical and functional consequences of isoprenylation/methylation are of especial interest. Isoprenylation/methylation is generally assumed to enhance the abilities of modified proteins to associate with membranes. This can be due either to hydrophobic lipid-lipid or lipid-protein interactions. Available evidence, taken largely from studies on visual signal transduction and ras signalling pathways, strongly points to enhanced membrane binding being a consequence of hydrophobic lipid-lipid interactions. An exciting possibility that also emerges is concerned with whether isoprenylation may also have additional roles, in addition to enhancing the membrane partitioning ability of the modified protein. In a simple mechanism of this type, the isoprenylated/methylated cysteine residue would be specifically recognized by another protein. While no compelling case can yet be made for an effector role for the isoprenylated/methylated cysteine moiety mediating protein-protein interactions, recent studies on the pharmacology of isoprenylated cysteine analogs suggests the possibility of such a role.

Novel methyltransferase activity modifying the carboxy terminal bis(geranylgeranyl)-Cys-Ala-Cys structure of small GTP-binding proteins

Proteins containing CX3, CXC, and CC (where C is cysteine and X is undefined) undergo posttranslational isoprenylation at their cysteine residues. In the case of proteins which terminate in CX3, proteolytic removal of X3 is followed by the carboxymethylation of the isoprenylated cysteine residue. CXC proteins also undergo C-terminal methylation. The present study addresses the question of whether this methylation is catalyzed by a different isoprenylated protein methyltransferase than that previously described for CX3 proteins. The S-adenosylmethionine (AdoMet) dependent methylation of a small peptide-N-acetyl-S-geranylgeranyl-L-cysteinyl-L-alanyl-S-geranylgeranyl- L- cysteine (Ac(GG)CysAla(GG)Cys)--was investigated using membranes from a variety of bovine tissues as sources of enzyme. Ac(GG)CysAla(GG)Cys was a substrate for methylation, while Ac(GG)Cys(GG)Cys was not. Reciprocal inhibition studies on the methylation reactions of the CXC peptide and of N-acetyl-S-farnesyl-L-cysteine (AFC), a previously described methyltransferase substrate, suggested that these reactions are catalyzed by distinct enzymatic activities. Farnesylthioacetic acid (FTA), a potent competitive inhibitor of the methylation of AFC, did not inhibit the methylation of the CXC peptide. Moreover the KI values for S-adenosylhomocysteine and S-adenosylethionine inhibition differed for the two enzymatic activities. These data indicate that more than one AdoMet-dependent methyltransferase is involved in the carboxymethylation of isoprenylated proteins.