Carboxy-terminal CFFL-sequence-specific monomeric protein geranylgeranyltransferase I from the eyes of the shrimp Penaeus japonicus

Farnesyl pyrophosphate promotes and is essential for the binding of RACK1 with beta-tubulin

Receptors for activated C kinase (RACKs) are a group of protein kinase C (PKC) binding proteins that have been shown to be crucial in the translocation and subsequent functioning of PKC on activation. RACK1 isolated from BALB/3T3 cells transformed with S-ras(Q61K) exhibits receptor activity for PKCgamma as competent as that of RACK1 from BALB/3T3 cells without transformation. However, the ability of RACK1 from transformed cells to bind with beta-tubulin peptide specific for Taxol (PEPtaxol) is defective. Interestingly, when farnesyl pyrophosphate was added at the submicrogram level, the association between RACK1 and PEPtaxol was enhanced significantly in a dosage-dependent manner. A parallel finding for the enhanced effect of farnesyl pyrophosphate on tubulin binding was established with mice RACK1 expressed in vitro. On the other hand, geranylgeranyl pyrophosphate, and retinoic acid failed to modulate the binding between RACK1 and tubulin. The dissociation of RACK1 and tubulin was not effective at damaging the binding between RACK1 and membrane receptor integrin beta1 in transformed cells. These findings indicate that depletion of farnesyl pyrophosphate provides a mechanism to seal PKC signaling on the membrane with immobile RACK1 and to divert cells to aberrant growth, such as transformation.

Effects of prenyl pyrophosphates on the binding of PKCgamma with RACK1

Receptors for activated C kinase (RACKs) are a group of PKC binding proteins that have been shown to mediate isoform-selective functions of PKC and to be crucial in the translocation and subsequent functioning of the PKC isoenzymes on activation. RACK1 cDNA from the shrimp Penaeus japonicus was isolated by homology cloning. The hepatopancreas cDNA from this shrimp was found to encode a 318-residue polypeptide whose predicted amino acid sequence shared 91% homology with human G(beta2)-like proteins. Expression of the cDNA of shrimp RACK1 in vitro yielded a 45-kDa polypeptide with positive reactivity toward the monoclonal antibodies against RACK1 of mammals. The shrimp RACK1 was biotinylated and used to compare the effects of geranylgeranyl pyrophosphate and farnesyl pyrophosphate on its binding with PKCgamma in anti-biotin-IgG precipitates. PKCgammas were isolated from shrimp eyes and mouse brains. Both enzyme preparations were able to inhibit taxol-induced tubulin polymerization. Interestingly, when either geranylgeranyl pyrophosphate or farnesyl pyrophosphate was reduced to the submicrogram level, the recruitment activity of RACK1 with purified PKCgamma was found to increase dramatically. The activation is especially significant for RACK1 and PKCgamma from different species. The observation implies that the deprivation of prenyl pyrophosphate might function as a signal for RACK1 to switch the binding from the conventional isoenzymes of PKC (cPKC) to the novel isoenzymes of PKC (nPKC). A hydrophobic binding pocket for geranylgeranyl pyrophosphate in RACK1 is further revealed via prenylation with protein geranylgeranyl transferase I of shrimp P. japonicus.

Effects of prenyl pyrophosphates on the binding of S-Ras proteins with KSR

BALB/3T3 cells were transformed by transfection with DNA encoding the mutated ras(Q(61)K) from shrimp Penaeus japonicus (Huang et al., 2001. J. Exp. Zool. 289:441-448). On a Western blot, the kinase suppressor of Ras (KSR) in the membrane fraction was expressed at slightly reduced level as compared to that of the untransformed cells. To understand this in more detail, the interaction of the bacterially expressed shrimp Ras (S-Ras) with KSR was investigated using KSR purified from mice brains. SDS-polyacrylamide gel electrophoresis and Western blot analysis revealed that the monomers of the purified KSR have a relative molecular mass of 60,000. Purified KSR was found to bind with digoxigenylated S-ras-encoding fusion protein (Dig-S-Ras) with high affinity in the absence of ATP, and the binding activity of KSR was sustained upon phosphorylation of Dig-S-Ras with mitogen-activated protein kinase (MAPK). The association of purified KSR with S-Ras was confirmed. Differences between the effects of farnesyl pyrophosphate and geranylgeranyl pyrophosphate on the binding of S-Ras with the purified KSR were assessed. Densitometer analysis revealed that at nanogram concentration, farnesyl pyrophosphate inhibited the binding of S-Ras with KSR competently, but geranylgeranyl pyrophosphate did not. The present study provides the evidence that decrease of the concentration of farnesyl pyrophosphate to sub-microgram levels lower the affinity of Ras proteins with KSR in the signaling pathway.

GTPase stimulation in shrimp Ras(Q(61)K) with geranylgeranyl pyrophosphate but not mammalian GAP

BALB/3T3 cells were transformed by transfection with DNA encoding the mutated ras(Q(61)K) from shrimp Penaeus japonicus (Huang et al., 2000). The GTPase-activating protein (GAP) in the cytosol fraction was significantly expressed and degraded, compared to untransformed cells on the western blot. To understand this in more detail, the interaction of the bacterially expressed shrimp Ras (S-Ras) with GAP was investigated using GAP purified from mouse brains. SDS-polyacrylamide gel electrophoresis revealed the monomers of the purified GAP to have a relative mass of 65,000. Since the purified GAP was bound to the Ras conjugated affinity sepharose column with high affinity and its GTP hydolysis activity upon binding with tubulin was suppressed, the purified enzyme was concluded to be neurofibromin-like. The purified GAP enhanced the intrinsic GTPase activity of the S-Ras, to convert it into the inactive GDP-bound form, in agreement with findings for GTP-bound K(B)-Ras in vitro. To compare the effects between isoprenoids and GAP on the GTP-hydrolysis of Ras, we applied the GTP-locked shrimp mutant S-Ras(Q(61)K) and GTP-locked rat mutant K(B)-ras(Q(61)K). Radioassay studies showed that geranylgeranyl pyrophosphate at microg level catalyzed the GTP hydrolysis of S-Ras(Q(61)K) and K(B)-ras(Q(61)K) competently, but not farnesyl pyrophosphate or the purified GAP. The present study provides the view that the geranylgeranyl pyrophosphate at carboxyl terminal CAAX assists GTP hydrolysis to Ras proteins probably in a manner similar to the substrate assisted catalysis in GTPase mechanism.

Disrupting the transforming activity of shrimpras(Q61K) by deleting the CAAX box at the C-terminus

BALB/3T3 cells were transformed by transfection with DNA encoding the mutated ras(Q(61)K) from shrimp Penaeus japonicus. Ras transcription and protein levels had increased significantly in the cells transfected with the S-ras plasmid, compared to cells transfected with a control plasmid pcDNA3.1. The bacterially expressed GTP-locked S-Ras(Q(61)K) is successfully prenylated by rat protein geranylgeranyltransferase I (PGGTase I) and then polymerized with tubulin, in agreement with findings for GTP-locked mammalian K(B)-Ras(Q(61)K) in vitro. Shrimp protein farnesyltransferase (PFTase) of shrimp did not prenylate the GTP-locked shrimp S-Ras(Q(61)K) (Lin and Chuang. 1998. J Exp Zool 281:565-573), whereas rat PFTase efficiently catalyzed the farnesylation of GTP-locked S-Ras(Q(61)K). To investigate the effect of geranylgeranylation on cellular transformation, we generated S-ras(Q(61)K) mutants with deletion of the CAAX box [S-ras(Q(61)K)(-caax)] or replacement of the CAAX box [S-ras(Q(61)K)(Kcaax)] or replacement of the arginine-rich domain [S-ras(Q(61)K)(K-Lys)] with corresponding sequences from rat K(B)-ras(Q(61)K). BALB/3T3 cells transfected with DNA encoding S-ras(Q(61)K), S-ras(Q(61)K)(KCAAX), S-ras(Q(61)K)(K-Lys) were transformed successfully, but S-ras(Q(61)K)(-CAAX) was defective in its ability to transform. Thus, prenylation at CAAX is required for transformation. Either the geranylgeranylated or the farnesylated S-Ras(Q(61)K) was endowed with abilities to transform. The arginine-rich region in S-Ras or the lysine-rich clusters from the rat K(B)-Ras appear not essential for activity to transform.

Disrupting the geranylgeranylation at the C-termini of the shrimp Ras by depriving guanine nucleotide binding at the N-terminal

In order to assess the effects of guanine nucleotide binding on the geranylgeranylation at the CAAX box of the shrimp Ras, we experimented with the shrimp Penaeus japonicus Ras (S-Ras) which is geranylgeranylated at the C-termini, shares 85% homology with mammalian K(B)-Ras protein and demonstrates identity in the guanine nucleotide binding domains (Huang C-F, Chuang N-N. 1999. J Exp Zool 283:510-521). Several point mutations in the S-ras gene were generated at codons 12 (G12V), 61 (Q61K), and 116 (N116I). The bacterially expressed mutant S-Ras proteins, G12V and Q61K, were bound with GTP without hydrolysis. In contrast, the mutant S-Ras N116I was defective in its ability to bind any guanine nucleotides. Autoradiography studies showed that the purified shrimp protein geranylgeranyltransferase I (Lin R-S, Chuang N-N. 1998. J Exp Zool 281:565-573) was unable to catalyze the transfer of [(3)H]-geranylgeranylpyrophosphate to this mutant N116I but very competently caused the geranylgeranylation of GTP-locked mutants, G12V and Q61K. These results demonstrate that the geranylgeranylation at the CAAX box of the shrimp Ras protein requires the proper binding of guanine nucleotide at its N-terminal region. J. Exp. Zool. 286:441-449, 2000.

Differential expression of ras in organs and embryos of shrimp Penaeus monodon (Crustacea: Decapoda)

Total RNA from shrimp hepatopancreas of Penaeus monodon showed three prominent bands that react with the shrimp ras probe, a 239-bp product, of approximately 4.8 kb (R1), 3.1 kb (R2) and 1.3 kb (R3) on the northern blot. The R1 is the least abundant. Analyses of total RNA from gill and heart were similar to each other. The highest expression of Ras was observed in the gill, while a negligible signal was detected with the Ras probe in muscle. Ras expression is developmentally regulated in embryonic stages of shrimp. Messenger RNA levels of ras were increased from a minimum in the nauplius stage to a maximum in the post-larvae stage for R1 and R2. R3 showed a maximum at the protozoea stage. On the other hand, the activity of protein geranylgeranyltransferase I was increased significantly in the early nauplius stage. No correlative increase of prenylation activity by protein geranylgeranyltransferase I was observed with the transcription activity of ras.

Molecular cloning of Ras cDNA from Penaeus japonicus (Crustacea, decapoda): geranylgeranylation and guanine nucleotide binding

A cDNA was isolated from the shrimp Penaeus japonicus by homology cloning. The shrimp hepatopancreas cDNA encodes a 187-residue polypeptide whose predicted amino acid sequence shares 85% homology with mammalian K-Ras 4B protein and demonstrates identity in the guanine nucleotide binding domains. Expression of the shrimp cDNA in Escherichia coli yielded a 21-kDa polypeptide with a positive reactivity towards the monoclonal antibodies against mammalian Ras. The GTP binding of the shrimp ras-encoded fusion protein was approximated to be 30000units/mg of protein, whereas the binding for GDP was 5000units/mg of protein. Fluorography analysis demonstrated that the prenylation of both shrimp Ras GDP and shrimp Ras GTP by protein geranylgeranyltransferase I of shrimp Penaeus japonicus exceeded the shrimp Ras nucleotide-free form by 10-fold, and fourfold, respectively; that is, the shrimp protein geranylgeranyltransferase I prefers to react with the shrimp ras-encoded p25 fusion protein in the GDP-bound form.