The ATP requiring step in assembly of M13 procoat protein into microsomes is related to preservation of transport competence of the precursor protein.

M13 procoat protein is processed to transmembrane coat protein by dog pancreas microsomes after completion of synthesis and in the absence of the signal recognition particle (SRP)/docking protein system. ATP is required for fast and efficient processing of procoat protein by microsomes in a reticulocyte lysate. Requirement for ATP is also observed in the absence of ribosomes or docking protein. This indicates the existence of a unique assembly pathway for procoat protein into microsomes which depends on ATP but does not depend on the SRP/docking protein and ribosome/ribosome receptor systems. We suggest that the ATP requirement is linked to a so far unknown component of the reticulocyte lysate, acting on transport competence of precursor proteins.     

Membrane assembly from purified components. I. Isolated M13 procoat does not require ribosomes or soluble proteins for processing by membranes

The coat protein of coliphage M13 is an integral protein of the host-cell cytoplasmic membrane prior to its assembly into virions. It is initially synthesized as procoat, a soluble precursor with a 23 amino acid leader sequence at its amino terminus. ³⁵S-labeled procoat accumulates during an in vitro translation reaction that contains ³⁵S-methionine and RNA from M13-infected cells. Radiochemically pure procoat has been isolated from in vitro translation reactions by extraction into an organic solvent and gel filtration through Sephadex LH-60. Radiochemically pure procoat can be used as substrate in rapid and quantitative assays for leader peptidase and for leader peptide hydrolase, an enzyme that degrades the leader peptide after its release from procoat. Procoat solubility, digestion by leader peptidase and processing by membranes are affected by the presence of Mg²⁺ ion. Isolated procoat is soluble in water at low ionic strength and mildly alkaline pH as well as in detergent solutions. It is cleaved to coat protein by purified E. coli leader peptidase and by inverted E. coli inner-membrane vesicles. These properties of the purified procoat mirror those of the procoat in crude extracts. This suggests that there are no other soluble components that are necessary for the assembly of procoat into the membrane and its conversion to coat; specifically, it provides powerful evidence that protein synthesis is not involved.     

M13 procoat inserts into liposomes in the absence of other membrane proteins

Procoat, the precursor form of the major coat protein of coliphage M13, assembles into the Escherichia coli inner membrane and is cleaved to mature coat protein by leader peptidase. This assembly process has previously been reconstituted using lipids and purified leader peptidase in a cell-free protein synthesis reaction (Watts, C., Silver, P., and Wickner, W. (1981) Cell 25, 347-353; Ohno-Iwashita, Y., and Wickner, W. (1983) J. Biol. Chem. 258, 1895-1900). We now report that procoat can also cross a liposomal membrane composed of only purified phospholipids; leader peptidase is not needed to catalyze insertion. When procoat is synthesized in vitro in the presence of liposomes with encapsulated chymotrypsin, the procoat inserts spontaneously through the membrane and is degraded. The protease was shown by several criteria to be in the lumen of the liposomes. These results demonstrate that the precursor form of an E. coli integral membrane protein can cross a membrane without the aid of leader peptidase or any other membrane proteins.     

Initial steps in protein membrane insertion. Bacteriophage M13 procoat protein binds to the membrane surface by electrostatic interaction.

Bacteriophage M13 procoat protein is synthesized on free polysomes prior to its assembly into the inner membrane of Escherichia coli. As an initial step of the membrane insertion pathway, the precursor protein interacts with the cytoplasmic face of the inner membrane. We have used oligonucleotide-directed mutagenesis to study the regions of the procoat protein involved in membrane binding. We find that there is an absolute requirement for positively charged amino acids at both ends of the protein. Replacing these with negatively charged residues resulted in an accumulation of the precursor in the cytoplasm. We propose that the positively charged amino acids are directly involved in membrane binding, possibly directly to the negatively charged phospholipid head groups. This was tested in vitro with artificial liposomes. Whereas wild-type procoat interacted with these liposomes, we found that procoat mutants with negatively charged amino acids at both ends did not bind. Therefore, we conclude that newly synthesized M13 procoat protein binds electrostatically to the negatively charged inner membrane of E. coli.     

Membrane assembly: Posttranslational insertion of M13 procoat protein into E. coli membranes and its proteolytic conversion to coat protein in vitro

The major coat protein (gene 8 product) of bacteriophage M13 is an integral membrane protein during infection of host cells. It is synthesized as a larger precursor (procoat) with a leader sequence of 23 amino acids at its amino terminus. In vivo studies have shown that procoat only inserts into the host-cell plasma membrane after its synthesis is completed. We now demonstrate that procoat can post-translationally insert into inverted cytoplasmic membrane vesicles from E. coli and can be processed proteolytically to yield coat protein. Procoat changes from an assembly-competent substrate to an incompetent (denatured) form within minutes after its synthesis; much of the procoat that accumulates during an hour of in vitro synthesis is therefore denatured. These studies emphasize the importance of stringent criteria for the demonstration of obligate cotranslational assembly.     

Recombinant forms of M13 procoat with an OmpA leader sequence or a large carboxy-terminal extension retain their independence of secY function.

The assembly of phage M13 procoat protein into the plasma membrane of Escherichia coli is independent of the secY protein. To test whether this is caused by the unusually small size of procoat, we fused DNA encoding 103 amino acids to the carboxy-terminal end of the procoat gene. The resulting fusion protein, which attains the same membrane-spanning conformation as mature coat protein, still does not require the secY function for membrane assembly. To determine whether the leader sequence governs interaction with the secY protein, we genetically exchanged the leader peptides between procoat and pro-OmpA, a protein which does require secY for its membrane assembly. Each of the resulting hybrid proteins assembles across the plasma membrane, though at a reduced rate. Membrane assembly of the fusion of procoat leader and OmpA required secY function, whereas assembly of the pro-OmpA leader/coat protein fusion was independent of secY. Properties of the entire procoat molecule, rather than its small size or a specific property of its leader peptide determines its mode of membrane assembly.     

Cysteine residues in the transmembrane regions of M13 procoat protein suggest that oligomeric coat proteins assemble onto phage progeny

The M13 phage assembles in the inner membrane of Escherichia coli. During maturation, about 2,700 copies of the major coat protein move from the membrane onto a single-stranded phage DNA molecule that extrudes out of the cell. The major coat protein is synthesized as a precursor, termed procoat protein, and inserts into the membrane via a Sec-independent pathway. It is processed by a leader peptidase from its leader (signal) peptide before it is assembled onto the phage DNA. The transmembrane regions of the procoat protein play an important role in all these processes. Using cysteine mutants with mutations in the transmembrane regions of the procoat and coat proteins, we investigated which of the residues are involved in multimer formation, interaction with the leader peptidase, and formation of M13 progeny particles. We found that most single cysteine residues do not interfere with the membrane insertion, processing, and assembly of the phage. Treatment of the cells with copper phenanthroline showed that the cysteine residues were readily engaged in dimer and multimer formation. This suggests that the coat proteins assemble into multimers before they proceed onto the nascent phage particles. In addition, we found that when a cysteine is located in the leader peptide at the -6 position, processing of the mutant procoat protein and of other exported proteins is affected. This inhibition of the leader peptidase results in death of the cell and shows that there are distinct amino acid residues in the M13 procoat protein involved at specific steps of the phage assembly process.     

Reconstitution of rapid and asymmetric assembly of M13 procoat protein into liposomes which have bacterial leader peptidase

The leader peptidase of Escherichia coli cleaves a 23-residue leader sequence from M13 procoat to yield mature coat protein in virus-infected cells. We have reconstituted pure leader peptidase into vesicles of E. coli lipids and found that these liposomes are active in the conversion of procoat to coat. Trypsin removes all but 10% of the leader peptidase, yet the vesicles retain nearly full capacity to convert procoat to coat, suggesting that only procoat which inserts across the liposomal membrane is a substrate for leader peptidase. This is confirmed by the finding that over 70% of the coat protein produced by these liposomes spans the membrane. The rate at which leader peptidase inside protease-treated liposomes cleaves externally added procoat is comparable to the rate of procoat cleavage by the same amount of leader peptidase in detergent micelles. Thus, procoat can rapidly integrate across a liposomal membrane and be cleaved to coat protein. These findings confirm the central part of the membrane trigger hypothesis that certain proteins (such as procoat) can cross a bilayer without the aid of a proteinaceous pore or transport system.     

M13 procoat protein insertion into YidC and SecYEG proteoliposomes and liposomes

M13 procoat protein was one of the first model proteins used to study bacterial membrane protein insertion. It contains a signal peptide of 23 amino acid residues and is not membrane targeted by the signal recognition particle. The translocation of its periplasmic domain is independent of the preprotein translocase (SecAYEG) but requires electrochemical membrane potential and the membrane insertase YidC of Escherichia coli. We show here that YidC is sufficient for efficient membrane insertion of the purified M13 procoat protein into energized YidC proteoliposomes. When no membrane potential is applied, the insertion is substantially reduced. Only in the presence of YidC, membrane insertion occurs if bilayer integrity is preserved and membrane potential is stable for more than 20 min. A mutant of the M13 procoat protein, H5EE, with two additional negatively charged residues in the periplasmic domain inserted into YidC proteoliposomes and SecYEG proteoliposomes with equal efficiencies. We conclude that the protein can use both the YidC-only pathway and the Sec pathway. This poses the questions of how procoat H5EE is inserted in vivo and how insertion pathways are selected in the cell.     

Conditional lethal mutations separate the M13 procoat and Pf3 coat functions of YidC: different YIDC structural requirements for membrane protein insertion

Conditional lethal YidC mutants have been isolated to decipher the role of YidC in the assembly of Sec-dependent and Sec-independent membrane proteins. We now show that the membrane insertion of the Sec-independent M13 procoat-lep protein is inhibited in a short time in a temperature-sensitive mutant when shifted to the nonpermissive temperature. This provides an additional line of evidence that YidC plays a direct role in the insertion of the Sec-independent M13 procoat protein. However, in the temperature-sensitive mutant, the insertion of the Sec-independent Pf3 phage coat protein and the Sec-dependent leader peptidase were not strongly inhibited at the restricted temperatures. Conversely, using a cold-sensitive YidC strain, we find that the membrane insertion of the Sec-independent Pf3 coat protein is blocked, and the Sec-dependent leader peptidase is inhibited at the nonpermissive temperature, whereas the insertion of the M13 procoat protein is nearly normal. These data show that the YidC function for procoat and its function for Pf3 coat and possibly leader peptidase are genetically separable and suggest that the YidC structural requirements are different for the Sec-independent M13 procoat and Pf3 coat phage proteins that insert by different mechanisms.     

Efficient translocation of positively charged residues of M13 procoat protein across the membrane excludes electrophoresis as the primary force for membrane insertion.

The coat protein of bacteriophage M13 is inserted into the Escherichia coli plasma membrane as a precursor protein, termed procoat, with a typical leader peptide of 23 amino acid residues. Its membrane insertion requires the electrochemical potential but not the cellular components SecA and SecY. Since the electrochemical gradients result in the periplasmic side of the membrane being positively charged, the membrane potential could contribute to the transfer of the negatively charged central region of procoat across the membrane. Here we demonstrate that the central domain following the leader peptide can be translocated across the membrane even when the net charge of the region is changed from -3 to +3. This rules out an electrophoresis-like insertion mechanism for procoat. We also show that the sec independence of procoat insertion is linked to the presence of the second apolar domain. The deletion of most of the second apolar domain from a procoat fusion protein results in sec dependent membrane insertion of the hybrid protein. Moreover, like other proteins that require the sec genes, translocation of this sec dependent procoat protein is inhibited when positively charged residues are introduced after the leader peptide. Loop models involving one or two hydrophobic regions are presented that account for the differences in tolerance of positively charged residues.     

Indecisive M13 procoat protein mutants bind to SecA but do not activate the translocation ATPase

The M13 procoat protein serves as the paradigm for the Sec-independent membrane insertion pathway. This protein is inserted into the inner membrane of Escherichia coli with two hydrophobic regions and a central periplasmic loop region of 20 amino acid residues. Extension of the periplasmic loop region renders M13 procoat membrane insertion Sec-dependent. Loop regions with 118 or more residues required SecA and SecYEG and were efficiently translocated in vivo. Two mutants having loop regions of 80 and 100 residues, respectively, interacted with SecA but failed to activate the membrane translocation ATPase of SecA in vitro. Similarly, a procoat mutant with two additional glutamyl residues in the loop region showed binding to SecA but did not stimulate the ATPase. The three mutants were also defective for precursor-stimulated binding of SecA to the membrane surface. Remarkably, the mutant proteins act as competitive inhibitors of the Sec translocase. This suggests that the region to be translocated is sensed by SecA but the activation of the SecA translocation ATPase is only successful for substrates with a minimum length of the translocated region.     

Both hydrophobic domains of M13 procoat are required to initiate membrane insertion.

M13 procoat protein has two hydrophobic domains, one in the leader peptide and one which anchors the mature coat protein in the membrane. Disruption of the membrane anchor region by insertion of arginyl residues does not yield periplasmic coat protein. Instead, the rate of membrane assembly is slowed greater than 100-fold (t1/2 less than 5 s for wild-type, t1/2 greater than 10 min for mutant). The hydrophobic region of mature coat protein not only functions as a membrane anchor, but has an important role in the membrane assembly process per se.     

Isolation of mutants in M13 coat protein that affect its synthesis, processing, and assembly into phage

The major coat protein (gene 8 protein) of bacteriophage M13 has been studied intensively as a model of membrane assembly, protein packing, and protein-DNA interactions. Because this protein is essential for assembly of the phage, very few mutants have been isolated. We have therefore cloned the gene 8 into a plasmid under control of the araB promoter. In the presence of arabinose, the cloned gene is expressed at a rate comparable to that in an M13-infected cell. Plasmid-derived procoat is inserted across the plasma membrane and processed to coat at a normal rate. The coat can support plaque formation by a defective M13 virus (M13am8) with an amber mutation in its procoat gene. This complementation assay was used to screen the mutagenized, cloned gene 8 for mutants which fail to make fully functional coat. Mutants were obtained which fail to synthesize procoat, which do not convert procoat to mature coat protein, or in which the coat protein is incapable of assembling into infectious virions.     

Seventy-kilodalton heat shock proteins and an additional component from reticulocyte lysate stimulate import of M13 procoat protein into microsomes.

Processing of M13 procoat protein, synthesized in a bacterial cell-free extract, to transmembrane coat protein by dog pancreas microsomes is stimulated by a system which is present in rabbit reticulocytes and depends on nucleoside triphosphates. This system consists of (at least) two components which act synergistically: members of the 70-kd heat shock protein family and (at least) one additional component. This component depends on ATP (or GTP) for its action.     

Polyoma large T antigen regulates the integration of viral DNA sequences into the genome of transformed cells

The major coat protein of coliphage M13 is an integral protein of the E. coli plasma membrane prior to its assembly into new virus particles. It is generated from its precursor, procoat, by a membrane-bound leader peptidase. We now describe the reconstitution of a highly purified preparation of this enzyme into vesicles of E. coli phospholipids. These vesicles bind procoat made in vitro and procoat isolated from in vitro synthesis. Both the crude and the purified substrates were converted posttranslationally to coat protein. A significant proportion of the coat protein becomes inserted into the vesicle bilayer, with the N terminus facing the vesicle interior and the C terminus exposed to the external medium. These results strongly suggest that highly purified leader peptidase from E. coli and phospholipids are the only components necessary to mediate the binding, processing and insertion of this integral membrane protein.     

The purification of M13 procoat, a membrane protein precursor.

Many membrane proteins and most secreted proteins are initially made as precursors with an N-terminal leader sequence. We now report the isolation of M13 procoat, the precursor of the membrane-bound form of M13 coat protein. There are 40 000 copies of M13 procoat protein/cell during M13 amber 7 virus infection. Purified procoat is quantitatively cleaved by isolated leader peptidase to yield mature-length coat protein. Rabbit antibodies to M13 procoat will precipitate procoat but not coat, suggesting that the antibody molecules are specifically recognizing the leader sequence or the conformation which it induces in the whole procoat molecule.     

Different regions of the nonconserved large periplasmic domain of Escherichia coli YidC are involved in the SecF interaction and membrane insertase activity

The YidC protein of Escherichia coli is required for inserting Sec-independent membrane proteins and has a supportive role for the insertion of Sec-dependent proteins into the membrane bilayer. Because a portion of YidC copurifies with the Sec translocase, this interaction might be necessary to assist in the membrane insertion of Sec-dependent proteins. This study describes a deletion analysis that investigates which parts of YidC are required for its interaction with the SecDF complex of the Sec translocase and for the function of YidC as an insertase for the Sec-dependent membrane proteins. The results suggest that the first periplasmic region, which includes residues 24-346, is required for the interaction of YidC with the Sec translocase, in particular with the SecF protein. Further studies showed that residues 215-265 of YidC are sufficient for SecF binding. Surprisingly, the interaction of YidC with SecF is not critical for cell viability as YidC, lacking residues 24-264, was fully functional to support the growth of E. coli. It was also observed that this YidC mutant was fully functional to insert the Sec-dependent subunit A of the F(1)F(o) ATP synthase and an M13 procoat derivative, as well as the Sec-independent M13 procoat protein and subunit C of the ATP synthase. Only when additional residues of the periplasmic region were deleted (265-346) was the membrane insertase function of YidC inhibited.     

Fluorescence resonance energy transfer shows a close helix-helix distance in the transmembrane M13 procoat protein

During the membrane insertion process the major coat protein of bacteriophage M13 assumes a conformation in which two transmembrane helices corresponding to the leader sequence and the anchor region in the mature part of the protein coming into close contact with each other. Previous studies on the molecular mechanism of membrane insertion of M13 procoat protein have shown that this interaction between the two helices might drive the actual translocation process. We investigated the intramolecular distance between the two helices of the transmembrane procoat protein by measuring fluorescence resonance energy transfer (FRET) between the donor (Tyr) placed in one helix and the acceptor (Trp) placed in the other helix. Various mutant procoat proteins with differently positioned donor-acceptor pairs were generated, purified, and reconstituted into artificial lipid bilayers. The results obtained from the FRET measurements, combined with molecular modeling, show that the transmembrane helices are in close contact on the order of 1-1.5 nm. The present approach might be of general interest for determining the topology and the folding of membrane proteins.     

Binding of inosine-substituted mRNA to reticulocyte ribosomes and eukaryotic initiation factors 4A and 4B requires ATP

We examined the hypothesis that initiation of eukaryotic protein synthesis involves ATP-dependent melting of 5'-cap-proximal secondary structure in mRNA by eukaryotic initiation factors 4A and 4B. In reticulocyte lysate depleted of ribonucleoside triphosphates by pretreatment with hexokinase/glucose, initiation complex formation by native reovirus mRNA showed a strict requirement for ATP. The corresponding mRNA synthesized with ITP in place of GTP to minimize secondary structure also required ATP for binding to 40 S ribosomal subunits in complexes characteristic of initiation. In a partial reaction without ribosomes, purified eukaryotic initiation factors 4A and 4B bound and cross-linked to the capped 5'-end of oxidized mRNA. This interaction was ATP-dependent with inosine-substituted or bromouridine-containing reovirus RNAs as observed previously with native mRNA. The results indicate that if initiation involves ATP-dependent denaturation of mRNA, the effect must occur after initiation factor-mediated attachment of mRNA to the 40 S ribosomal subunit.