In vitro assembly,purification, and crystallization of the rab geranylgeranyl transferase:substrate complex

Posttranslational modification with the geranygeranyl moiety is essential for the ability of Rab GTPases to control processes of membrane docking and fusion. This modification is conferred by Rab geranylgeranyltransferase (RabGGTase), which catalyzes the transfer of two 20-carbon geranylgeranyl groups from geranylgeranyl pyrophosphate onto C-terminal cysteine residues of Rab proteins. The enzyme consists of a catalytic alpha/beta heterodimer and an accessory protein termed Rab escort protein (REP-1) that delivers the newly prenylated Rab proteins to their target membrane. In order to understand the structural basis of Rab prenylation, we have investigated in vitro assembly and crystallization of the RabGGTase:REP-1:Rab complex. In order to ensure maximal stability of the ternary complex, we generated its monoprenylated form, which corresponds to a reaction intermediate and displays the highest affinity between the components. This was achieved by expressing the individual components in baculovirus and Escherichia coli systems with subsequent purification followed by in vitro monoprenylation of Rab7 with immobilized recombinant RabGGTase. Purified monoprenylated REP-1:Rab7 was complexed with recombinant RabGGTase and crystallized in hanging drops. The crystals obtained initially diffract to 8 A on an in-house X-ray source.     

Membrane targeting of a Rab GTPase that fails to associate with Rab escort protein (REP) or guanine nucleotide dissociation inhibitor (GDI)

The targeting of various Rab proteins to different subcellular compartments appears to be determined by variable amino acid sequences located upstream from geranylgeranylated cysteine residues in the C-terminal tail. All nascent Rab proteins are prenylated by geranylgeranyltransferase II, which recognizes the Rab substrate only when it is bound to Rab escort protein (REP). After prenylation, REP remains associated with the modified Rab until it is delivered to the appropriate subcellular membrane. It remains unclear whether docking of the Rab with the correct membrane is solely a function of features contained within the prenylated Rab itself (with REP serving as a "passive" carrier) or whether REP actively participates in the targeting process. To address this issue, we took advantage of a mutation in the alpha2 helix of Rab1B (i.e. Y78D) that abolishes REP and GDI interaction without disrupting nucleotide binding or hydrolysis. These studies demonstrate that replacing the C-terminal GGCC residues of Rab1B(Y78D) with a CLLL motif permits this protein to be prenylated by geranylgeranyltransferase I but not II both in cell-free enzyme assays and in transfected cells. Subcellular fractionation and immunofluorescence studies reveal that the prenylated Rab1B(Y78D)CLLL, which remains deficient in REP and GDI association is, nonetheless, delivered to the Golgi and endoplasmic reticulum (ER) membranes. When the dominant-negative S22N mutation was inserted into Rab1B-CLLL, the resulting monoprenylated construct suppressed ER --> Golgi protein transport. However, when the Y78D mutation was added to the latter construct, its inhibitory effect on protein trafficking was lost despite the fact that it was localized to the ER/Golgi membrane. Therefore, protein interactions mediated by the alpha2 helical domain of Rab1B(S22N) appear to be essential for its functional interaction with components of the ER --> Golgi transport machinery.     

Properties of Rab5 N-terminal domain dictate prenylation of C-terminal cysteines.

Rab5 is a Ras-related GTP-binding protein that is post-translationally modified by prenylation. We report here that an N-terminal domain contained within the first 22 amino acids of Rab5 is critical for efficient geranylgeranylation of the protein's C-terminal cysteines. This domain is immediately upstream from the "phosphate binding loop" common to all GTP-binding proteins and contains a highly conserved sequence recognized among members of the Rab family, referred to here as the YXYLFK motif. A truncation mutant that lacks this domain (Rab5(23-215) fails to become prenylated. However, a chimeric peptide with the conserved motif replacing cognate Rab5 sequence (MAYDYLFKRab5(23-215) does become post-translationally modified, demonstrating that the presence of this simple six amino acid N-terminal element enables prenylation at Rab5's C-terminus. H-Ras/Rab5 chimeras that include the conserved YXYLFK motif at the N-terminus do not become prenylated, indicating that, while this element may be necessary for prenylation of Rab proteins, it alone is not sufficient to confer properties to a heterologous protein to enable substrate recognition by the Rab geranylgeranyl transferase. Deletion analysis and studies of point mutants further reveal that the lysine residue of the YXYLFK motif is an absolute requirement to enable geranylgeranylation of Rab proteins. Functional studies support the idea that this domain is not required for guanine nucleotide binding since prenylation-defective mutants still bind GDP and are protected from protease digestion in the presence of GTP gamma S. We conclude that the mechanism of Rab geranylgeranylation involves key elements of the protein's tertiary structure including a conserved N-terminal amino acid motif (YXYLFK) that incorporates a critical lysine residue.     

Expression of mammalian geranylgeranyltransferase type-II in Escherichia coli and its application for in vitro prenylation of Rab proteins

Mammalian geranylgeranyltransferase type II (GGTase-II) is a 100-kDa heterodimer that catalyzes the transfer of two 20-carbon geranylgeranyl groups from geranylgeranyl pyrophosphate onto C-terminal cysteine residues of Rab GTPases. This modification is essential for the biological activity of Rab proteins. Geranylgeranylation can be performed in vitro using recombinant GGTase-II but so far large-scale production of the enzyme was challenging. We report here the design of a two plasmid expression system that will produce GGTase-II at levels as high as 15 mg/L in Escherichia coli. The protein was produced as a heterodimer with the alpha subunit bearing a cleavable tandem 6His-glutathione S-transferase (GST) tag that was used for two-step purification of the enzyme. Purified enzyme was functionally active as determined by in vitro prenylation and phosphoisoprenoid binding assay. Furthermore, the GST-tagged GGTase-II was used for preparative in vitro prenylation of the Rab7:REP-1 complex. Using this procedure, 10 mg of doubly prenylated Rab7:REP-1 complex were obtained.     

Direct production of proteins with N-terminal cysteine for site-specific conjugation

Proteins with N-terminal cysteine can undergo native chemical ligation and are useful for site-specific N-terminal labeling or protein semisynthesis. Recombinant production of these has usually been by site-specific cleavage of a precursor fusion protein at an internal cysteine residue. Here we describe a simpler route to producing these proteins. Overexpression in E. coli of several proteins containing cysteine as the second amino acid residue yielded products in which the initiating methionine residue had been completely cleaved by endogenous methionine aminopeptidase. While secondary modification of the terminal cysteine was a complicating factor, conditions were identified to eliminate or minimize this problem. Recombinant proteins produced in this way were suitable for site-specific modification of the amino terminus via native chemical ligation technology, as demonstrated by conjugation of a thioester-containing derivative of fluorescein to one such protein. The ability to directly produce proteins with N-terminal cysteine should simplify the application of native chemical ligation technology to recombinant proteins and make the technique more amenable to researchers with limited expertise in protein chemistry.     

Allosteric regulation of substrate binding and product release in geranylgeranyltransferase type II

GTPases of the Rab family are key components of vesicular transport in eukaryotic cells. Posttranslational attachment of geranylgeranyl moieties is essential for Rab function. Geranylgeranyltransferase type II (GGTase-II) catalyzes the modification of Rab proteins once they are in complex with their escort protein (REP). Upon completion of prenylation, REP and modified Rab leave the enzyme, enabling a new round of catalysis. We have studied the mechanism underlying substrate binding and product release in the geranylgeranylation of Rab proteins. Binding of the Rab7:REP-1 complex to GGTase-II was found to be strongly modulated by geranylgeranyl pyrophosphate (GGpp). The affinity of GGTase-II for the Rab7:REP-1 complex increases from ca. 120 nM to ca. 2 nM in the presence of GGpp. To study the effect of GGpp on interaction of the enzyme with its product, we generated semisynthetic doubly prenylated Rab7 bearing a fluorescent reporter group. Using this novel compound, we demonstrated that the affinity of doubly prenylated Rab7:REP-1 complex for GGTase-II was 2 and 18 nM in the absence and presence of GGpp, respectively. The difference in affinities originates mainly from a difference in the dissociation rates. Thus, binding of the new isoprenoid substrate molecule facilitates the product release by GGTase-II. The affinity of GGpp for the prenylated Rab7:REP-1:GGTase-II was K(d) = 22 nM, with one molecule of GGpp binding per molecule of prenylated ternary complex. We interpreted this finding as an indication that the geranylgeranyl moieties transferred to Rab protein do not occupy the GGpp binding site of the GGTase-II. In summary, these results demonstrate that GGpp acts as an allosteric activator that stabilizes the Rab7:REP-1:GGTase-II complex and triggers product release upon prenylation, preventing product inhibition of the enzyme.     

Double prenylation by RabGGTase can proceed without dissociation of the mono-prenylated intermediate

Rab geranylgeranyltransferase (RabGGTase) catalyzes the prenylation of Rab proteins. Despite possessing a single active site, RabGGTase is able to add geranylgeranyl moieties onto each of the two C-terminal cysteine residues of Rab. We have studied the kinetics of Rab double prenylation employing a combination of a novel high pressure liquid chromatography (HPLC)-based in vitro prenylation assay and fluorescence spectroscopy. Transfer of the first geranylgeranyl group proceeds with a k(1) = 0.16 s(-1), while the conversion from singly to double prenylated Rab is 4-fold slower (k(2) = 0.039 s(-1)). We found that following the first transfer reaction, the conjugated lipid is removed from the active site of RabGGTase but mono-prenylated Rab.REP complex remains bound to RabGGTase with a K(d) < 1 nm. In contrast to the doubly prenylated Rab7.REP dissociation of the mono-prenylated species from RabGGTase was only weakly stimulated by phosphoisoprenoid. Based on the obtained rate constants we calculated that at least 72% of mono-prenylated Rab molecules proceed to double prenylation without dissociating from RabGGTase. The obtained data provides an explanation of how RabGGTase discriminates between mono-prenylated intermediate and double prenylated reaction product. It also indicates that the phosphoisoprenoid acts both as a substrate and as a sensor governing the kinetics of protein.protein interactions in the double prenylation reaction.     

Rab GTPases containing a CAAX motif are processed post-geranylgeranylation by proteolysis and methylation

Post-translational modification by protein prenylation is required for membrane targeting and biological function of monomeric GTPases. Ras and Rho proteins possess a C-terminal CAAX motif (C is cysteine, A is usually an aliphatic residue, and X is any amino acid), in which the cysteine is prenylated, followed by proteolytic cleavage of the AAX peptide and carboxyl methylation by the Rce1 CAAX protease and Icmt methyltransferase, respectively. Rab GTPases usually undergo double geranylgeranylation within CC or CXC motifs. However, very little is known about processing and membrane targeting of Rabs that naturally contain a CAAX motif. We show here that a variety of Rab-CAAX proteins undergo carboxyl methylation, both in vitro and in vivo, with one exception. Rab38(CAKS) is not methylated in vivo, presumably because of the inhibitory action of the lysine residue within the AAX motif for cleavage by Rce1. Unlike farnesylated Ras proteins, we observed no targeting defects of overexpressed Rab-CAAX proteins in cells deficient in Rce1 or Icmt, as reported for geranylgeranylated Rho proteins. However, endogenous geranylgeranylated non-methylated Rab-CAAX and Rab-CXC proteins were significantly redistributed to the cytosol at steady-state levels and redistribution correlates with higher affinity of RabGDI for non-methylated Rabs in Icmt-deficient cells. Our data suggest a role for methylation in Rab function by regulating the cycle of Rab membrane recruitment and retrieval. Our findings also imply that those Rabs that undergo post-prenylation processing follow an indirect targeting pathway requiring initial endoplasmic reticulum membrane association prior to specific organelle targeting.     

The prenylation of proteins.

The prenylated proteins represent a newly discovered class of post-translationally modified proteins. The known prenylated proteins include the oncogene product p21ras and other low molecular weight GTP-binding proteins, the nuclear lamins, and the gamma subunit of the heterotrimeric G proteins. The modification involves the covalent attachment of a 15-carbon (farnesyl) or 20-carbon (geranylgeranyl) isoprenoid moiety in a thioether linkage to carboxyl terminal cysteine. The nature of the attached substituent is dependent on specific sequence information in the carboxyl terminus of the protein. In addition, prenylation entrains other posttranslational modifications forming a reaction pathway. In this article, we review our current understanding of the biochemical reactions involved in prenylation and discuss the possible role of this modification in the control of cellular functions such as protein maturation and cell growth.     

Rab escort protein-1 is a multifunctional protein that accompanies newly prenylated rab proteins to their target membranes.

Rab proteins comprise a family of small GTPases that serve a regulatory role in vesicular membrane traffic. Geranylgeranylation of these proteins on C-terminal cysteine motifs is crucial for their membrane association and function. This post-translational modification is catalysed by rab geranylgeranyl transferase (Rab-GGTase), a multisubunit enzyme consisting of a catalytic heterodimer and an accessory component, named rab escort protein (REP)-1. Previous in vitro studies have suggested that REP-1 presents newly synthesized rab proteins to the catalytic component of the enzyme, and forms a stable complex with the prenylated proteins following the transfer reaction. According to this model, a cellular factor would be required to dissociate the rab protein from REP-1 and to allow it to recycle in the prenylation reaction. RabGDP dissociation inhibitor (RabGDI) was considered an ideal candidate for this role, given its established function in mediating membrane association of prenylated rab proteins. Here we demonstrate that dissociation from REP-1 and binding of rab proteins to the membrane do not require RabGDI or other cytosolic factors. The mechanism of REP-1-mediated membrane association of rab5 appears to be very similar to that mediated by RabGDI. Furthermore, REP-1 and RabGDI share several other functional properties, the ability to inhibit the release of GDP and to remove rab proteins from membranes; however, RabGDI cannot assist in the prenylation reaction. These data suggest that REP-1 is per se sufficient to chaperone newly prenylated rab proteins to their target membranes.     

Antigenic prenylated peptide conjugates and polyclonal antibodies to detect protein prenylation

Posttranslational modification of proteins with farnesyl and geranylgeranyl groups is a required modification for signaling proteins that includes the small GTPases in the Ras, Rho, and Rab families, heterotrimeric G proteins, and nuclear lamin proteins. To develop antibodies capable of detecting and distinguishing prenylated proteins, we synthesized two antigens, succinylglycine-(geranylgeranyl)cysteine methyl ester (SuccG-(gg)CMe, 1) and succinylglycine-(farnesyl)cysteine methyl ester (SuccG-(f)CMe, 2). These prenylated peptides were covalently coupled to bovine serum albumin (BSA) and to keyhole limpet hemocyanin (KLH) to produce polyvalent, immunogenic bioconjugates. Immunization of rabbits with these immunogens generated polyclonal antisera that contained significant titers of anti-geranylgeranyl and anti-farnesyl antibodies. The selectivity of the polyclonal antisera was examined using ELISA and dot blotting methods. The anti-farnesyl and anti-geranylgeranyl antisera crossreacted with both antigens. Attempts to purify the polyclonal antisera by either positive or negative immunoaffinity selection protocols failed to produce selective anti-geranylgeranyl and anti-farnesyl antibodies. Moreover, both crude antisera and purified antibodies also crossreacted with myristoylated and palmitoylated BSA conjugates. Immunofluorescence staining of EYFP-CVLL or EYFP-CVIM transfected CHO-K1 cells with rabbit polyclonal antisera showed colocalized membrane fluorescence. Thus, an important caveat for the use of antibodies raised against aliphatic antigens is that extensive controls must be performed to determine selectivity.     

The effector domain of Rab6, plus a highly hydrophobic C terminus, is required for Golgi apparatus localization.

C-terminal lipid modifications are essential for the interaction of Ras-related proteins with membranes. While all Ras proteins are farnesylated and some palmitoylated, the majority of other Ras-related proteins are geranylgeranylated. One such protein, Rab6, is associated with the Golgi apparatus and has a C-terminal CXC motif that is geranylgeranylated on both cysteines. We show here that farnesylation alone cannot substitute for geranylgeranylation in targeting Rab6 to the Golgi apparatus and that whereas Ras proteins that are farnesylated and palmitoylated are targeted to the plasma membrane, mutant Rab proteins that are both farnesylated and palmitoylated associate with the Golgi apparatus. Using chimeric Ras-Rab proteins, we find that there are sequences in the N-terminal 71 amino acids of Rab6 which are required for Golgi complex localization and show that these sequences comprise or include the effector domain. The C-terminal hypervariable domain is not essential for the Golgi complex targeting of Rab6 but is required to prevent prenylated and palmitoylated Rab6 from localizing to the plasma membrane. Functional analysis of these mutant Rab6 proteins in Saccharomyces cerevisiae shows that wild-type Rab6 and C-terminal mutant Rab6 proteins which localize to the Golgi apparatus in mammalian cells can complement the temperature-sensitive phenotype of ypt6 null mutants. Interestingly, therefore, the C-terminal hypervariable domain of Rab6 is not required for this protein to function in S. cerevisiae.     

Prenylated Rab acceptor protein is a receptor for prenylated small GTPases

Localization of Ras and Ras-like proteins to the correct subcellular compartment is essential for these proteins to mediate their biological effects. Many members of the Ras superfamily (Ha-Ras, N-Ras, TC21, and RhoA) are prenylated in the cytoplasm and then transit through the endomembrane system on their way to the plasma membrane. The proteins that aid in the trafficking of the small GTPases have not been well characterized. We report here that prenylated Rab acceptor protein (PRA1), which others previously identified as a prenylation-dependent receptor for Rab proteins, also interacts with Ha-Ras, RhoA, TC21, and Rap1a. The interaction of these small GTPases with PRA1 requires their post-translational modification by prenylation. The prenylation-dependent association of PRA1 with multiple GTPases is conserved in evolution; the yeast PRA1 protein associates with both Ha-Ras and RhoA. Earlier studies reported the presence of PRA1 in the Golgi, and we show here that PRA1 co-localizes with Ha-Ras and RhoA in the Golgi compartment. We suggest that PRA1 acts as an escort protein for small GTPases by binding to the hydrophobic isoprenoid moieties of the small GTPases and facilitates their trafficking through the endomembrane system.     

Membrane topography and topogenesis of prenylated Rab acceptor (PRA1)

The mouse prenylated Rab acceptor (mPRA1) is associated with the Golgi membrane at steady state and interacts with Rab proteins. It contains two internal hydrophobic domains (34 residues each) that have enough residues to form four transmembrane (TM) segments. In this study, we have determined the membrane topography of mPRA1 in both intact cells and isolated microsomes. The putative TM segments of mPRA1 were used to substitute for a known TM segment of a model membrane protein to determine whether the mPRA1 segments integrate into the membrane. Furthermore, N-linked glycosylation scanning methods were used to distinguish luminal domains from cytoplasmic domains of mPRA1. The data demonstrate that mPRA1 is a polytopic membrane protein containing four TM segments. These TM segments act cooperatively during the translocation and integration at the endoplasmic reticulum membrane. All hydrophilic domains are in the cytoplasm, including the N-terminal domain, the linker domain between the two hydrophobic domains, and the C-terminal domain. As a result, the bulk of mPRA1 is located in the cytoplasm, supporting its postulated role in regulating Rab membrane targeting and intracellular trafficking.     

Rab geranylgeranyl transferase. A multisubunit enzyme that prenylates GTP-binding proteins terminating in Cys-X-Cys or Cys-Cys.

Rab proteins are membrane-bound prenylated GTP-binding proteins required for the targeted movement of membrane vesicles from one organelle to another. In the current paper we have characterized and purified an enzyme that attaches geranylgeranyl residues to Rab proteins that bear the COOH-terminal sequence Cys-X-Cys (such as Rab3A) and Cys-Cys (such as Rab1A). This enzyme is designated Rab geranylgeranyl transferase (Rab GG transferase). At high salt concentrations, Rab GG transferase from rat brain cytosol separates into two components, designated A and B, both of which are required for activity. We purified Component B to apparent homogeneity and found that it contains two peptides of 60 and 38 kDa. The purified Rab GG transferase did not attach geranylgeranyl to p21H-ras-CVLL, which is prenylated by a GG transferase of the CAAX type that resembles the CAAX farnesyltransferase. Rab GG transferase was strongly inhibited by Zn2+, a cation that is absolutely required by farnesyltransferase. The Rab GG transferase was also inhibited by NaCl concentrations in excess of 100 mM. Together with previous data, the current findings indicate that mammalian cells possess at least three protein prenyltransferases (CAAX farnesyltransferase, CAAX GG transferase, and Rab GG transferase) that are specific for different classes of low molecular weight GTP-binding proteins and other proteins.     

Photoreceptor cGMP phosphodiesterase delta subunit (PDEdelta) functions as a prenyl-binding protein

Bovine PDEdelta was originally copurified with rod cGMP phosphodiesterase (PDE) and shown to interact with prenylated, carboxymethylated C-terminal Cys residues. Other studies showed that PDEdelta can interact with several small GTPases including Rab13, Ras, Rap, and Rho6, all of which are prenylated, as well as the N-terminal portion of retinitis pigmentosa GTPase regulator and Arl2/Arl3, which are not prenylated. We show by immunocytochemistry with a PDEdelta-specific antibody that PDEdelta is present in rods and cones. We find by yeast two-hybrid screening with a PDEdelta bait that it can interact with farnesylated rhodopsin kinase (GRK1) and that prenylation is essential for this interaction. In vitro binding assays indicate that both recombinant farnesylated GRK1 and geranylgeranylated GRK7 co-precipitate with a glutathione S-transferase-PDEdelta fusion protein. Using fluorescence resonance energy transfer techniques exploiting the intrinsic tryptophan fluorescence of PDEdelta and dansylated prenyl cysteines as fluorescent ligands, we show that PDEdelta specifically binds geranylgeranyl and farnesyl moieties with a Kd of 19.06 and 0.70 microm, respectively. Our experiments establish that PDEdelta functions as a prenyl-binding protein interacting with multiple prenylated proteins.     

A structural model of the GDP dissociation inhibitor rab membrane extraction mechanism

Rab GDP dissociation inhibitors (GDI)-facilitated extraction of prenylated Rab proteins from membranes plays an important role in vesicular membrane trafficking. The investigated thermodynamic properties of yeast Rab.GDI and Rab.MRS6 complexes demonstrated differences in the Rab binding properties of the closely related Rab GDI and MRS6 proteins, consistent with their functional diversity. The importance of the Rab C terminus and its prenylation for GDI/MRS6 binding was demonstrated using both biochemical and structural data. The presented structures of the apo-form yeast Rab GDI and its two complexes with unprenylated Rab proteins, together with the earlier published structures of the prenylated Ypt1.GDI, provide evidence of allosteric regulation of the GDI lipid binding site opening, which plays a key role in the proposed mechanism of GDI-mediated Rab extraction. We suggest a model for the interaction of GDI with prenylated Rab proteins that incorporates a stepwise increase in affinity as the three different partial interactions are successively formed.     

Ras (CXXX) and Rab (CC/CXC) prenylation signal sequences are unique and functionally distinct.

Rab proteins typically lack the consensus carboxyl-terminal CXXX motif that signals isoprenoid modification of Ras and other isoprenylated proteins and, instead, terminate in either CC or CXC sequences (C = cysteine, X = any amino acid). To compare the functional relationship between the Ras CXXX and the Rab CC/CXC motifs, we have generated chimeric Ras proteins terminating in Rab carboxyl-terminal CC or CXC sequences. These mutant Ras proteins were not isoprenylated in vitro or in vivo, demonstrating that the CC and CXC sequences alone are not sufficient to replace a CXXX sequence to signal Ras isoprenoid modification. Surprisingly, chimeric Ras/Rab proteins terminating in significant lengths of carboxyl-terminal sequences from Rab1b (7-139 residues), Rab2 (5-151 residues), or Rab3a (12 residues) were also not isoprenylated. These results demonstrate that the sequence requirements for isoprenoid modification of Rab proteins are more complex than the simple tetrapeptide CXXX sequence for isoprenoid modification of Ras proteins and suggest that the Rab geranylgeranyl transferase(s) requires recognition of protein conformation to signal the addition of geranylgeranyl groups. Finally, competition studies demonstrate that a common geranylgeranyl transferase activity is responsible for the modification of Rab proteins terminating in CC or CXC motifs.     

Modification of Rab5 with a photoactivatable analog of geranylgeranyl diphosphate

A photoprobe analog of geranylgeranyl diphosphate (2-diazo-3,3,3-trifluoropropionyloxy-farnesyl diphosphate or DATFP-FPP) inhibits mevalonate-dependent prenylation of in vitro translated Rab5 in rabbit reticulocyte lysate, suggesting that it competes for lipid binding to the Rab geranylgeranyl transferase. Modification of Rab5 with DATFP-FPP, demonstrated by gel mobility shift and Triton X-114 phase separation experiments, confirms that the enzyme uses the analog as a substrate. The sedimentation of DATFP-modified Rab5 as a larger mass complex on sucrose density gradients indicates that it binds to other factors in rabbit reticulocyte lysate. Most importantly, DATFP-Rab5 cross-links to these soluble factors upon exposure to UV light. Immunoprecipitation with antibodies raised against proteins known to interact with Rab5 reveals that the cross-linked complexes contain Rab escort protein and GDI-1. DATFP-Rab5 also associates with membranes in a guanosine-5'-O-(3-thiotriphosphate)-stimulated manner. However, although prenylated Rab5 can be cross-linked to two unknown membrane-associated factors by the chemical cross-linker disuccinimidyl suberate, these proteins fail to be UV cross-linked to membrane-bound DATFP-Rab5. These results strongly suggest that membrane-associated factors bind Rab5 through protein-protein interactions rather than protein-prenyl interactions. The modification of Rab5 with DATFP-FPP establishes a novel photoaffinity technique for the characterization of prenyl-binding sites.     

Polyoxazoline-peptide adducts that retain antibody avidity

Synthetic polymers have long been used to modify various properties of proteins such as activity and solubility. Polyethylene glycol (PEG) has been widely used to form adducts with enzymes and antibodies. In this study, the polyoxazoline family of water-soluble polymers was used to synthesize adducts containing a synthetic peptide recognized by a monoclonal antibody (MAb) directed against human protein C (hPC). This is the first application of direct conjugation of unterminated or "living" polymer to a peptide. The avidity of the antibody for the various adducts was characterized with respect to size and hydrophilicity of methyl- and ethyl-substituted polyoxazoline polymers (POX). Avidity of the adducts was not found to be dependent upon the hydrophilicity and was slightly decreased due to polymer modification. The methyl-POX-peptide adducts were found to be highly water soluble, while the ethyl-POX-peptide adducts showed sporadic problems with aqueous solubility. Because the polymer-peptide adducts retained avidity for the antibody, polyoxazoline polymers may have potential application to protein-adduct chemistry.