Insertion of a signal peptide-derived hydrophobic segment into the mature domain of OmpC, an outer membrane protein, does not interfere with the export of the following polypeptide chain across the cytoplasmic membrane of E. coli

The effects of a hydrophobic peptide segment inserted into the amino-terminal region of the mature domain of OmpC, an outer membrane protein, on its translocation across the cytoplasmic membrane was studied. Both the intact OmpC and central domain-deleted OmpC were examined. The hydrophobic segment was derived from the signal peptide of OmpF. Secretory translocation across the cytoplasmic membrane was examined by means of proteinase K treatment. Four monoclonal antibodies that recognize different regions of OmpC were used to characterize proteinase K-resistant fragments. Insertion of the hydrophobic segment did not appreciably prevent the translocation of these proteins across the cytoplasmic membrane, larger parts of them being found as mature forms, which were mostly localized outside the cytoplasmic membrane. Circumstantial evidence supports the view, on the other hand, that the inserted hydrophobic domain was retained in the cytoplasmic membrane. It is concluded, therefore, that the hydrophobic segment, although it is not exported across the cytoplasmic membrane, does not prevent the secretion of the following polypeptide chain. The secretion was dependent on the amino-terminal signal peptide. Insertion of positive charges immediately after the hydrophobic segment resulted in suppression of the translocation. Based on these results possible mechanisms by which the secretion of the polypeptide chain after the hydrophobic segment are discussed.     

Protease IV, a cytoplasmic membrane protein of Escherichia coli, has signal peptide peptidase activity

During export of the outer membrane lipoprotein across the cytoplasmic membrane, the signal peptide of the lipoprotein undergoes two successive proteolytic attacks, cleavage of the signal peptide by signal peptidase and digestion of the cleaved signal peptide by an enzyme called signal peptide peptidase(s) (Hussain, M., Ichihara, S., and Mizushima, S. (1982) J. Biol. Chem. 257, 5177-5182; Hussain, M., Ozawa, Y., Ichihara, S., and Mizushima, S. (1982) Eur. J. Biochem. 129, 233-239). Here we report that protease IV, a cytoplasmic membrane protease, exhibits the signal peptide peptidase activity. The signal peptide peptidase activity was cofractionated with protease IV throughout the entire process of purification of the latter enzyme. Only the signal peptide was digested by the peptidase among membrane proteins. Both the signal peptide peptidase activity and the protease IV activity were inhibited to similar degrees by antipain, leupeptin, chymostatin, and elastatinal that are known to inhibit the signal peptide peptidase activity in the cell envelope. From these results we conclude that protease IV is the signal peptide peptidase that is responsible for signal peptide digestion in the cytoplasmic membrane. The peptidase attacked the signal peptide only after its release from the precursor protein.     

Degradation of a signal peptide by protease IV and oligopeptidase A.

The degradation of the prolipoprotein signal peptide in vitro by membranes, cytoplasmic fraction, and two purified major signal peptide peptidases from Escherichia coli was followed by reverse-phase liquid chromatography (RPLC). The cytoplasmic fraction hydrolyzed the signal peptide completely into amino acids. In contrast, many peptide fragments accumulated as final products during the cleavage by a membrane fraction. Most of the peptides were similar to the peptides formed during the cleavage of the signal peptide by the purified membrane-bound signal peptide peptidase, protease IV. Peptide fragments generated during the cleavage of the signal peptide by protease IV and a cytoplasmic enzyme, oligopeptidase A, were identified from their amino acid compositions, their retention times during RPLC, and knowledge of the amino acid sequence of the signal peptide. Both enzymes were endopeptidases, as neither dipeptides nor free amino acids were formed during the cleavage reactions. Protease IV cleaved the signal peptide predominantly in the hydrophobic segment (residues 7 to 14). Protease IV required substrates with hydrophobic amino acids at the primary and the adjacent substrate-binding sites, with a minimum of three amino acids on either side of the scissile bond. Oligopeptidase A cleaved peptides (minimally five residues) that had either alanine or glycine at the P'1 (primary binding site) or at the P1 (preceding P'1) site of the substrate. These results support the hypothesis that protease IV is the major signal peptide peptidase in membranes that initiates the degradation of the signal peptide by making endoproteolytic cuts; oligopeptidase A and other cytoplasmic enzymes further degrade the partially degraded portions of the signal peptide that may be diffused or transported back into the cytoplasm from the membranes.     

Secretion into the culture medium of a foreign gene product from Escherichia coli: use of the ompF gene for secretion of human beta-endorphin.

The ompF gene codes for a major outer membrane protein of Escherichia coli. A plasmid was constructed in which the structural gene for human beta-endorphin is preceded by the upstream region of the ompF gene consisting of the promoter region and the coding regions for the signal peptide and the N terminus of the OmpF protein. When the plasmid was introduced into E. coli N99, and OmpF-beta-endorphin fused peptide was synthesized and secreted into the culture medium through both the cytoplasmic and outer membranes. The OmpF signal peptide was cleaved correctly during the secretion, indicating that the export of the fused protein across the cytoplasmic membrane was dependent on the signal peptide. The secretion into the culture medium was apparently selective. Neither beta-lactamase nor alkaline phosphatase (both are periplasmic proteins) appeared in the culture medium in significant amounts. The mode of passage of the fused peptide across the outer membrane is discussed.     

Crystal structure of a bacterial signal Peptide peptidase

Signal peptide peptidase (Spp) is the enzyme responsible for cleaving the remnant signal peptides left behind in the membrane following Sec-dependent protein secretion. Spp activity appears to be present in all cell types, eukaryotic, prokaryotic and archaeal. Here we report the first structure of a signal peptide peptidase, that of the Escherichia coli SppA (SppA_EC). SppA_EC forms a tetrameric assembly with a novel bowl-shaped architecture. The bowl has a dramatically hydrophobic interior and contains four separate active sites that utilize a Ser/Lys catalytic dyad mechanism. Our structural analysis of SppA reveals that while in many Gram-negative bacteria as well as characterized plant variants, a tandem duplication in the protein fold creates an intact active site at the interface between the repeated domains, other species, particularly Gram-positive and archaeal organisms, encode half-size, unduplicated SppA variants that could form similar oligomers to their duplicated counterparts, but using an octamer arrangement and with the catalytic residues provided by neighboring monomers. The structure reveals a similarity in the protein fold between the domains in the periplasmic Ser/Lys protease SppA and the monomers seen in the cytoplasmic Ser/His/Asp protease ClpP. We propose that SppA may, in addition to its role in signal peptide hydrolysis, have a role in the quality assurance of periplasmic and membrane-bound proteins, similar to the role that ClpP plays for cytoplasmic proteins.     

Export and processing of MalE-LacZ hybrid proteins in Escherichia coli

Five classes of MalE-LacZ hybrid proteins have previously been characterized. These proteins differ in the amount of the maltose-binding protein (MBP) that is attached to beta-galactosidase. Although none of these proteins is secreted into the periplasm, the four larger classes of hybrid proteins, those that include an intact MBP signal peptide, are inserted into the cytoplasmic membrane, suggesting that the secretion process has at least been initiated. In this study, we demonstrated that some portion of the four larger hybrid proteins can be translocated across the cytoplasmic membrane, thus permitting processing of the signal peptide. We have found that hybrid proteins that include only a small portion of the mature MBP are inefficiently recognized as exported proteins, and translocation and processing of these appear to be relatively slow, posttranslational events. In marked contrast, hybrid proteins that include a substantial portion of the mature MBP are efficiently recognized, and translocation and processing of these occur very rapidly, possibly cotranslationally. Our results complement other studies and very strongly suggest a role for the mature MBP in the export process.     

The flaFIX gene product of Salmonella typhimurium is a flagellar basal body component with a signal peptide for export.

flaFIX, the structural gene for the periplasmic P ring of the flagellar basal body of Salmonella typhimurium, was cloned. Two gene products with apparent molecular weights of 38,000 and 40,000 were identified by minicell analysis. Data from pulse-chase and membrane fractionation experiments and data on the inhibitory effect of the proton ionophore carbonyl cyanide m-chlorophenylhydrazone all indicated that the 40-kilodalton protein was a precursor form which, after export across the cytoplasmic membrane accompanied by cleavage of a signal peptide, gave rise to the mature protein in the periplasm. The N-terminal amino acid sequence of the FlaFIX protein, predicted from the DNA sequence, conformed well to known signal peptide sequences. The results indicate that the P-ring protein of the basal body (unlike flagellin and possible some other external flagellar components) crosses the cytoplasmic membrane in a conventional signal peptide-dependent manner.     

Identification of a region in the cytoplasmic domain of the platelet membrane glycoprotein Ib-IX complex that binds to purified actin-binding protein.

The platelet membrane glycoprotein (GP) Ib-IX complex is a major site of attachment of the platelet membrane skeleton to the plasma membrane. This association is mediated by the interaction of actin-binding protein with the GP Ib-IX complex. The aim of the present work was to identify domains on the GP Ib-IX complex that interact with actin-binding protein. Synthetic peptides corresponding to sequences of the GP Ib alpha-chain and beta-chain cytoplasmic domains were analyzed for their ability to bind to purified actin-binding protein. Two overlapping peptides encompassing a sequence (Thr-536-Phe-568) from the central region of the cytoplasmic domain of GP Ib alpha were the most effective in binding 125I-actin-binding protein, as assessed by a microtiter well approach and peptide affinity chromatography. One of the active peptides (Thr-536-Leu-554) was chosen to evaluate the likelihood that the central region of the cytoplasmic domain of GP Ib alpha is involved in binding of the intact complex to actin-binding protein. This peptide could be specifically cross-linked to purified actin-binding protein in solution. Rabbit polyclonal antibody against this peptide inhibited the binding of purified actin-binding protein to the purified GP Ib-IX complex. Finally, as in intact platelets, the calpain-induced hydrolytic fragments of purified actin-binding protein (M(r) = 200,000 and M(r) = 91,000) showed little binding to the GP Ib alpha peptide. Taken together, these results provided evidence that a region between Thr-536 and Phe-568 of the cytoplasmic domain of GP Ib alpha participates in the interaction of the GP Ib-IX complex with actin-binding protein.     

Effects of signal peptide and adenylate on the oligomerization and membrane binding of soluble SecA

SecA protein, a cytoplasmic ATPase, plays a central role in the secretion of signal peptide-containing proteins. Here, we examined effects of signal peptide and ATP on the oligomerization, conformational change, and membrane binding of SecA. The wild-type (WT) signal peptide from the ribose-binding protein inhibited ATP binding to soluble SecA and stimulated release of ATP already bound to the protein. The signal peptide enhanced the oligomerization of soluble SecA, while ATP induced dissociation of SecA oligomer. Analysis of SecA unfolding with urea or heat revealed that the WT signal peptide induces an open conformation of soluble SecA, while ATP increased the compactness of SecA. We further obtained evidences that the signal peptide-induced oligomerization and the formation of open structure enhance the membrane binding of SecA, whereas ATP inhibits the interaction of soluble SecA with membranes. On the other hand, the complex of membrane-bound SecA and signal peptide was shown to resume nucleotide-binding activity. From these results, we propose that the translocation components affect the degree of oligomerization of soluble SecA, thereby modulating the membrane binding of SecA in early translocation pathway. A possible sequential interaction of SecA with signal peptide, ATP, and cytoplasmic membrane is discussed.     

Mechanism of signal peptide cleavage in the biosynthesis of the major lipoprotein of the Escherichia coli outer membrane

On treatment of Escherichia coli cells with globomycin, a glyceride-containing precursor of the major outer membrane lipoprotein accumulates in the cytoplasmic membrane (Hussain, M., Ichihara, S., and Mizushima, S. (1980) J. Biol. Chem. 255, 3707-3712). When the envelope fraction from such cells was incubated in a suitable buffer, this precursor could be processed to the mature lipoprotein. The processing involved removal of the signal peptide and subsequent acylation of the NH2 terminus thus bared. Two types of peptidase and an acylation enzyme(s) were found to be involved in these processes. The enzyme that cleaves the signal peptide, called signal peptidase in this paper, had many unique properties: being highly resistant to high temperature, having a wide optimum pH range, and being highly sensitive to detergents. The other peptidase(s), called signal peptide peptidase in this paper, was assumed to be responsible for the digestion of the signal peptide that had been cleaved from the precursor lipoprotein. This enzyme was rather heat-sensitive. Thus the processing from the precursor to the mature lipoprotein at a high temperature resulted in accumulation of a peptide that was most probably the intact signal peptide. The third enzyme(s) involved in the processing was the one that is responsible for acylation of the newly bared NH2 terminus of the lipoprotein. The enzyme activity was also lost at 80 degrees C. In the light of these findings, the biosynthetic pathway of the lipoprotein is discussed.     

The stable BRP signal peptide causes lethality but is unable to provoke the translocation of cloacin DF13 across the cytoplasmic membrane of Escherichia coli

The bacteriocin release protein (BRP) mediates the secretion of cloacin DF13. The BRP precursor is slowly processed to yield the mature BRP and its stable signal peptide which is also involved in cloacin DF13 secretion. The function of the stable BRP signal peptide was analysed by constructing two plasmids. First, the stable BRP signal peptide was fused to the murein lipoprotein and, second, a stop codon was introduced after the BRP signal sequence. Exchange of the unstable murein lipoprotein signal peptide for the stable BRP signal peptide resulted in an accumulation of precursors of the hybrid murein lipoprotein. This indicated that the BRP signal peptide, as part of this hybrid precursor, is responsible for the slow processing. The stable BRP signal peptide itself was not able to direct the transfer of cloacin DF13 into the periplasmic space or into the culture medium. Over-expression of the BRP signal peptide was lethal and caused 'lysis'. Subcellular fractionation experiments revealed that the BRP signal peptide is located exclusively in the cytoplasmic membrane whereas the mature BRP, targeted by either the stable BRP signal peptide or the unstable Lpp signal peptide, is located in both the cytoplasmic and outer membrane. These results are in agreement with the hypothesis that the stable signal peptide and the mature BRP together are required for the passage of cloacin DF13 across the cell envelope.     

The Rhodobacter sphaeroides cytochrome c2 signal peptide is not necessary for export and heme attachment.

Rhodobacter sphaeroides cytochrome c2 (cyt c2) is a member of the heme-containing cytochrome c protein family that is found in the periplasmic space of this gram-negative bacterium. This exported polypeptide is made as a higher-molecular-weight precursor with a typical procaryotic signal peptide. Therefore, cyt c2 maturation is normally expected to involve precursor translocation across the cytoplasmic membrane, cleavage of the signal peptide, and covalent heme attachment. Surprisingly, synthesis as a precursor polypeptide is not a prerequisite for cyt c2 maturation because deleting the entire signal peptide does not prevent export, heme attachment, or function. Although cytochrome levels were reduced about threefold in cells containing this mutant protein, steady-state cyt c2 levels were significantly higher than those of other exported bacterial polypeptides which contain analogous signal peptide deletions. Thus, this mutant protein has the unique ability to be translocated across the cytoplasmic membrane in the absence of a signal peptide. The covalent association of heme with this mutant protein also suggests that the signal peptide is not required for ligand attachment to the polypeptide chain. These results have uncovered some novel aspects of bacterial c-type cytochrome biosynthesis.     

Testing the '+2 rule' for lipoprotein sorting in the Escherichia coli cell envelope with a new genetic selection

We report a novel strategy for selecting mutations that mislocalize lipoproteins within the Escherichia coli cell envelope and describe the mutants obtained. A strain carrying a deletion of the chromosomal malE gene, coding for the periplasmic maltose-binding protein (MalE), cannot use maltose unless a wild-type copy of malE is present in trans. Replacement of the natural signal peptide of preMalE by the signal peptide and the first four amino acids of a cytoplasmic membrane-anchored lipoprotein resulted in N-terminal fatty acylation of MalE (lipoMalE) and anchoring to the periplasmic face of the cytoplasmic membrane, where it could still function. When the aspartate at position +2 of this protein was replaced by a serine, lipoMalE was sorted to the outer membrane, where it could not function. Chemical mutagenesis followed by selection for maltose-using mutants resulted in the identification of two classes of mutations. The single class I mutant carried a plasmid-borne mutation that replaced the serine at position +2 by phenylalanine. Systematic substitutions of the amino acid at position +2 revealed that, besides phenylalanine, tryptophan, tyrosine, glycine and proline could all replace classical cytoplasmic membrane lipoprotein sorting signal (aspartate +2). Analysis of known and putative lipoproteins encoded by the E. coli K-12 genome indicated that these amino acids are rarely found at position +2. In the class II mutants, a chromosomal mutation caused small and variable amounts of lipoMalE to remain associated with the cytoplasmic membrane. Similar amounts of another, endogenous outer membrane lipoprotein, NlpD, were also present in the cytoplasmic membrane in these mutants, indicating a minor, general defect in the sorting of outer membrane lipoproteins. Four representative class II mutants analysed were shown not to carry mutations in the lolA or lolB genes, known to be involved in the sorting of lipoproteins to the outer membrane.     

The organization of the major protein of the human erythrocyte membrane

The enzyme lactoperoxidase was used to catalyse the radioiodination of membrane proteins in intact human erythrocytes and in erythrocyte `ghosts'. Two major proteins of the erythrocyte membrane were isolated after iodination of these two preparations, and the peptide `maps' of each protein so labelled were compared. Peptides from both proteins are labelled in the intact cell. In addition, further mobile peptides derived from one of the proteins are labelled only in the `ghost' preparation. Various sealed `ghost' preparations were also iodinated, lactoperoxidase being present only at either the cytoplasmic or extra-cellular surface of the membrane. The peptide `maps' of protein E (the major membrane protein) labelled in each case were compared. Two discrete sets of labelled peptides were consistently found. One group is obtained when lactoperoxidase is present at the extra-cellular surface and the other group is found when the enzyme is accessible only to the cytoplasmic surface of the membrane. The results support the assumption that the organization of protein E in the membrane of the intact erythrocyte is unaltered on making erythrocyte `ghosts'. They also confirm previous suggestions that both the sialoglycoprotein and protein E extend through the human erythrocyte membrane.     

Trigger factor interacts with the signal peptide of nascent Tat substrates but does not play a critical role in Tat-mediated export.

Twin-arginine translocation (Tat)-mediated protein transport across the bacterial cytoplasmic membrane occurs only after synthesis and folding of the substrate protein that contains a signal peptide with a characteristic twin-arginine motif. This implies that premature contact between the Tat signal peptide and the Tat translocon in the membrane must be prevented. We used site-specific photo-crosslinking to demonstrate that the signal peptide of nascent Tat proteins is in close proximity to the chaperone and peptidyl-prolyl isomerase trigger factor (TF). The contact with TF was strictly dependent on the context of the translating ribosome, started early in biogenesis when the nascent chain left the ribosome near L23, and persisted until the chain reached its full length. Despite this exclusive and prolonged contact, depletion or overexpression of TF had little effect on the kinetics and efficiency of the Tat export process.     

The stable bacteriocin release protein signal peptide, expressed as a separate entity, functions in the release of cloacin DF13

Abstract The pCloDF1S encoded bacteriocin release protein (BRP) plays a role in the release of the bacteriocin cloacin DF13. The BRP signal peptide is stable after cleavage, and accumulates in the cytoplasmic membrane. A BRP which is correctly targeted by the unstable murein lipoprotein signal peptide (Lpp-BRP) is not capable of inducing the release of cloacin DF13. To investigate the role of the stable BRP signal peptide in the release of cloacin DF13, the stable BRP signal peptide and the Lpp-BRP were expressed in trans in cells also producing cloacin DF13. Expression and release experiments indicate that the stable signal peptide can complement the Lpp-BRP in the release of cloacin DF13.     

Synthetic peptides corresponding to residues 551 to 555 and 650 to 653 of the rat testicular follicle-stimulating hormone (FSH) receptor are sufficient for post-receptor modulation of Sertoli cell responsiveness to FSH stimulation

We have recently demonstrated that synthetic peptides corresponding to the third cytoplasmic (3i) loop (residues 533 to 555) and a region in the carboxy-terminal cytoplasmic tail (residues 645 to 653) of the rat testicular follicle-stimulating hormone receptor (FSHR) affected signal transduction in rat testis membranes and cultured rat Sertoli cells. In order to define more precisely the peptide domains involved, we synthesized truncated peptide amides corresponding to FSHR residues 551–555 (KIAKR) and 650–653 (RKSH), respectively. These two regions were chosen since they contained a minimal structural motif present in G protein activator regions of several other G protein-coupled receptors (i.e., B-X-X-B-B or B-B-X-B, B representing a basic amino acid). Neither peptide inhibited binding of FSH to testis membrane receptors. Each peptide significantly reduced FSH-stimulated estradiol biosynthesis by intact cultured rat Sertoli cells. The same results were obtained with streptolysin O-permeabilized Sertoli cells. No effect was noted on forskolin-induced steroidogenesis, indicating that the peptide effects were not due to interaction with adenylyl cyclase. Each peptide amide, however, induced concentration-dependent increases in guanine nucleotide exchange in rat testis membranes. Our results indicate that interaction of FSH receptor with its associated G protein may involve relatively restricted peptide sequences, and include residues 551–555 (KIAKR) in the third cytoplasmic loop, and residues 650–653 (RKSH) in the carboxy-terminal cytoplasmic tail of the FSH receptor.     

Signal peptide mutants ofEscherichia coli

Numerous secretory proteins of the Gram-negative bacteriaE. coli are synthesized as precursor proteins which require an amino terminal extension known as the signal peptide for translocation across the cytoplasmic membrane. Following translocation, the signal peptide is proteolytically cleaved from the precursor to produce the mature exported protein. Signal peptides do not exhibit sequence homology, but invariably share common structural features: (1) The basic amino acid residues positioned at the amino terminus of the signal peptide are probably involved in precursor protein binding to the cytoplasmic membrane surface. (2) A stretch of 10 to 15 nonpolar amino acid residues form a hydrophobic core in the signal peptide which can insert into the lipid bilayer. (3) Small residues capable of -turn formation are located at the cleavage site in the carboxyl terminus of the signal peptide. (4) Charge characteristics of the amino terminal region of the mature protein can also influence precursor protein export. A variety of mutations in each of the structurally distinct regions of the signal peptide have been constructedvia site-directed mutagenesis or isolated through genetic selection. These mutants have shed considerable light on the structure and function of the signal peptide and are reviewed here.     

The interaction of mammalian medium-chain hydrolase with yeast fatty acid synthetase

The prolipoprotein, a secretory precursor of the outer membrane lipoprotein of Escherichia coli, is known to be accumulated in the cell envelope when cells are grown in the presence of a cyclic antibiotic, globomycin. The prolipoprotein was localized in the cytoplasmic membrane when it was separated from the outer membrane by sucrose-density gradient centrifugation. However, when the envelope fraction was treated with sodium sarcosinate, the prolipoprotein was found almost exclusively in the sarcosinate-insoluble outer membrane fraction. The prolipoprotein separated in the cytoplasmic membrane by sucrose-density gradient centrifugation was soluble in sarcosinate and could not form a complex with the outer membrane once solubilized in sarcosinate. Labeling of the two lysine residues at positions 2 and 5 of the prolipoprotein with [3H]dinitrophenylfluorobenzene was enhanced 26-fold when the cells were disrupted by sonication. On the other hand, a tryptic fragment of the ompA protein, which is known to exist in the periplasmic space, increased its susceptibility to [3H]dinitrophenylfluorobenzene only 5.3-times upon disruption of the cell structure. These results indicate that the prolipoprotein accumulated in the presence of globomycin is translocated across the cytoplasmic membrane and interacts with the outer membrane. At the same time, it is attached to the cytoplasmic membrane with its amino-terminal signal peptide in such a way that the amino-terminal portion of the signal peptide containing two lysine residues is left inside the cytoplasm.     

Cellular import of synthetic peptide using a cell-permeable sequence in plant protoplasts

In this paper, we describe a rapid method to incorporate biologically active synthetic peptide in plant protoplasts. The peptides used contain a hydrophobic membrane permeable sequence as a carrier for the import through the plasma membrane. The membrane permeable sequence corresponds to the h-region, the more hydrophobic domain found in the signal peptide of secreted proteins. To evaluate the feasibility of the method, we synthesized a cell-permeable peptide with an h-region of a plant signal peptide plus residues 410–419 of the human c-myc oncogene product. Detection was performed via fluorescence analysis using specific monoclonal anti-c-myc primary antibody and FITC-conjugated secondary antibody. No saturation of import was observed, suggesting that the mechanisms involved do not require energy. The half-life time of the internalized peptide was estimated and results indicate that peptide concentration into protoplasts was constant for 8 h following incorporation. This method is complementary to microinjection or to the use of membrane permeabilizing reagents to study in vivo protein–protein or DNA–protein interactions. Finally, this method was used to analyse a putative interaction between the conserved cytoplasmic tail of a transmembrane receptor (HaELP, Helianthus annuus EGF receptor like protein) and the cytoskeleton. No interaction was found between these components.