Diacylglycerol Specifically Blocks Spontaneous Integration of Membrane Proteins and Allows Detection of a Factor-assisted Integration*

We recently found that the spontaneous integration of M13 procoat is blocked by diacylglycerol (DAG) (Nishiyama, K., Ikegami, A., Moser, M., Schiltz, E., Tokuda, H., and Muller, M. (2006) J. Biol. Chem. 281, 35667–35676). Here, we demonstrate that the spontaneous integration of Pf3 coat, another membrane protein that has been thought to be integrated spontaneously into liposomes, can be blocked by DAG at physiological concentrations. Moreover, the spontaneous integration of the membrane potential-independent version of Pf3 coat (3L-Pf3 coat), which is independent of YidC, was also blocked by DAG. To clarify the mechanism by which DAG blocks spontaneous integration, we examined lipid compounds similar to DAG and DAG derivatives. The blockage of spontaneous integration was specific to DAG, as fatty acids, monoacylglycerol, and phosphatidic acids were not effective for the blockage. When the acyl chains in DAG were shortened even to octanoyl residues, it still blocked spontaneous integration, whereas diheptanoylglycerol did not block it at all. Triacylglycerol was more effective than DAG. However, the lipid A-derivative-dependent integration of M13 procoat could not be reconstituted when triacylglycerol was included in the liposomes. On the other hand, when DAG was included in the liposomes, we found that the integration of 3L-Pf3 coat was strictly dependent on the lipid A-derived integration factor. We propose that the bulky structure of DAG rather than changes in membrane curvature is essential for the blockage of spontaneous integration. We also demonstrated that the blockage of spontaneous integration by DAG is also operative in native membrane vesicles.

Integral membrane proteins in Escherichia coli are integrated into the cytoplasmic membrane through defined steps. Many membrane proteins are cotranslationally targeted to membranes with the help of the signal recognition particle (SRP) 2 / SRP receptor system followed by membrane integration at the SecYEG site (for a review, see Ref. 1). Several membrane proteins, such as M13 procoat, Pf3 coat, CyoA, and F 0 c subunit, are integrated independently of both SRP and SecYEG, as these proteins are integrated into Sec-or SRP-deficient membranes (2)(3)(4)(5)(6)(7)(8). YidC, a homologue of mitochondrial Oxa1p and Alb3p in chloroplasts, is thought to be involved in the integration of such SecYEG-independent proteins, as YidC depletion caused the accumulation of the precursor form of M13 procoat (9). On the other hand, M13 procoat can be efficiently integrated into liposomes composed of polar phospholipids even in the absence of a membrane potential (7), and therefore, these proteins have long been thought to be integrated "spontaneously." Although the YidC-dependent integration of Pf3 coat (10) and F 0 c subunit (11,12) has been reconstituted in proteoliposomes, the experimental conditions used in those studies allow spontaneous integration. Indeed, the integration of a potential-independent version of Pf3 coat, 3L-Pf3 coat, was reported to occur into liposomes free of YidC, suggesting that the spontaneous mechanism of membrane protein integrations was still operative (10). In in vivo studies, it has been shown that integration of both M13 procoat and Pf3 coat is strongly dependent on YidC (9,13). On the other hand, the generation of a proton motive force is severely impaired by YidC depletion (3), which should inhibit the integration of these potential-dependent proteins. Moreover, M13 procoat is resistant to alkaline extraction even after YidC depletion (14), indicating that even the potential-dependent protein is integrated into membranes in a YidC-independent manner. Therefore, the YidC dependence for the integration of these membrane proteins is still unsettled.
We have been studying the mechanisms underlying the membrane integration of MtlA, which possesses 6 -8 predicted transmembrane regions (15,16). MtlA integration is absolutely dependent on both the SRP system and SecYEG (17,18). On the contrary, we found that MtlA is spontaneously integrated into liposomes in the complete absence of SecYEG (19), similarly to Sec-independent substrates. Therefore, such spontaneous integration of MtlA could only be an in vitro artifact. We further found that MtlA integration into liposomes could be reduced and blocked by including diacylglycerol (DAG) in liposomes at a physiological concentration (19), and this finding enabled us to reconstitute MtlA integration in a SecYEG-dependent manner. Moreover, using this reconstitution system, we found a lipid A-derived integration stimulating factor that is involved in the integration of both MtlA and M13 procoat (19).
In this study we examined the effects of chemically synthesized lipids on the blockage of spontaneous integration, as we previously used DAG enzymatically prepared from an E. coli extract of polar phospholipids. We found that the spontaneous integration, including that of potential-independent 3L-Pf3 coat, was indeed blocked specifically by DAG at the concentration close to the in vivo conditions. Moreover, we found that in the presence of DAG, 3L-Pf3 coat integration was dependent on the lipid A-derived integration-stimulating factor.
Plasmid pTD1, which carries dgkA under the control of the tac promoter, was constructed as follows. A pair of primers dgkfor (AA GAT CTT AGG AGG TTT AAA TTT ATG GCC AAT AAT ACC ACT) and dgkrev (G GTC GAC TTA TCC AAA ATG CGA CCA TA) was used to PCR amplify the dgkA gene with the MC4100 chromosome as a template. The restriction sites of BglII and SalI, attached to both ends, respectively, are shown in italics. Underlined indicate the initiation and termination codons, respectively. The dgkA gene fragment, thus, created was cloned into pUSI2 (24) which had been digested with BglII and SalI.
Preparation of Liposomes-Liposomes containing DAG or other lipids were prepared as follows. Polar phospholipids and DAG or other lipids were mixed in chloroform and then evaporated under a stream of nitrogen gas and then under vacuum. To the dried lipid mixture, buffer A (50 mM triethanolamine acetate (pH 7.5), 1 mM dithiothreitol) was added to give a concentration of 10 mg of phospholipids/ml, and then liposomes were obtained by means of a bath sonicator. To prepare large liposomes, the dried lipid mixture suspended in buffer A as described above was frozen and thawed and then passed through the polycarbonate filter (400 nm pore size) 10 times by means of an extruder (Avanti Polar Lipids) according to the manufacturer's instruction.
Reconstitution of the Integration-stimulating Factor into Proteoliposomes-Proteoliposomes containing the integrationstimulating factor were reconstituted as described (19). Briefly, the purified factor (25 g) was mixed with polar phospholipids (0.2 mg) and 10 g of either 1,2-dioleoyl-sn-glycerol or trioleoylglycerol in 100 l of buffer A containing 1.5% octylglucoside. Proteoliposomes were reconstituted by dialyzing the mixture against buffer A. The proteoliposome suspension, thus obtained, was diluted with 1 ml of buffer A and then sedimented by centrifugation (170,000 ϫ g for 1 h at 4°C). After suspending proteoliposomes in 50 l of buffer A, they were frozen, thawed, and then sonicated (27). An aliquot (5 l) was subjected to the integration assay.
Integration Assay-In vitro synthesis of membrane proteins and integration reactions were essentially performed as described (19). The in vitro protein synthesis mixture, composed of amino acids other than Met and Cys (40 M each), 35 S-labeled Met and Cys (2-5 MBq/ml), 250 M ATP, 50 M CTP, GTP, and UTP, 2 mM dithiothreitol, 8 mM creatine phosphate, 12 mM phosphoenolpyruvate, 2.4 mM spermidine, 40 g/ml creatine kinase, fractionated cytosolic translation factors (28), salt-washed ribosomes (29), initiation factor 2 (18), and 600 units/ml T7 RNA polymerase, were mixed with plasmids and (proteo)liposomes (400 g of phospholipids/ml) or INVs (250 g of protein/ml) in buffer B (40 mM triethanolamine acetate (pH 7.5), 150 mM potassium acetate, and 7.5 mM magnesium acetate). The reaction mixtures (50 l) were incubated at 37°C for 30 min and then divided in two parts. The first part (30 l) was mixed with an equal volume of proteinase K (1 mg/ml) and digested for 20 min at 25°C followed by trichloroacetic acid (5%) precipitation. The other part (15 l) was precipitated with trichloroacetic acid (5%) directly. All samples were analyzed on SDS gels (30) containing 6 M urea (19). Radiolabeled materials were visualized and quantitated by means of a PhosphorImager (GE Healthcare).
Determination of the DAG Content in the Cell-The overnight culture (10 l) was inoculated in the LB medium (1 ml) containing 74 kBq/ml [ 14 C] palmitate (PerkinElmer Life Sciences) followed by cultivation at 37°C for 3 h. Cells, recovered by centrifugation (10,000 ϫ g for 5 min), were suspended in 50 l of 50 mM sodium phosphate (pH 7.2), 1 mM EDTA. After the treatment with lysozyme (0.1 mg/ml), cells were lysed by sonication. Triton X-100 was then added to the lysate at 0.2% and incubated on ice for 10 min to solubilize membranes followed by centrifugation (10,000 ϫ g for 10 min at 4°C). An aliquot of the supernatant (1 l) was directly subjected to TLC analysis as described (31).

Integration of 3L-Pf3 Coat Is Independent of Both the Membrane Potential and YidC but Does Not Occur Spontaneously-To
examine the effect of DAG on the blockage of spontaneous integration, we employed three types of membrane proteins that are known to be integrated into liposomes spontaneously. They are M13 H5 procoat (26), which we used in the previous study (19), Pf3 coat, and 3L-Pf3 coat, a potential-independent version of Pf3 coat (8). M13 H5 procoat is integrated similarly to wild type M13 procoat, except that the signal sequence is not cleaved (32). As reported previously (8,19), all of these proteins were integrated into INVs prepared from the wild type strain (wild type INVs) efficiently ( Fig. 1). In the case of M13 H5 procoat and Pf3 coat, their integration was reduced by half on the addition of DCCD to dissipate the proton motive force (PMF), confirming that the integration of these proteins is stimulated by the membrane potential, a component of PMF ( Fig. 1, A and  B). On the other hand, 3L-Pf3 coat integration was not reduced on the addition of DCCD (Fig. 1C), as reported (8). When YidCdepleted INVs (⌬YidC INVs) were used, 3L-Pf3 coat integration was rather slightly increased compared with that into wild type INVs. Moreover, 3L-Pf3 coat integration into ⌬YidC INVs was not affected irrespective of the presence or absence of PMF (Fig. 1C). In contrast, the integration of M13 H5 procoat and Pf3 coat into ⌬YidC INVs was slightly impaired, consistent with previous reports (10,13,19). Thus, the integration of 3L-Pf3 coat was independent of both PMF and YidC, whereas M13 H5 procoat and Pf3 coat integration was reduced in the absence of YidC or PMF. Taken together, these results and the observation that the integration of 3L-Pf3 coat is both Sec-and SRP-independent (10) indicate that 3L-Pf3 coat seems to be integrated into membranes spontaneously without any help by integration factors. We next examined the integration activities using liposomes ( Fig. 1, right). When liposomes composed of polar phospholipids were used, all the membrane proteins used here were integrated more efficiently than into INVs treated with DCCD. 3L-Pf3 coat integration into liposomes was more significant than that of the other two proteins, because PMF was not imposed in liposomes. In marked contrast, when liposomes containing DAG were used, almost no integration activity for any of these proteins was observed (Fig. 1). Therefore, these proteins are not spontaneously integrated into liposomes if DAG is present, as seen for MtlA integration (19).
DAG Specifically Blocks Spontaneous Integration-We next examined whether the blockage of spontaneous integration is specific to DAG. In addition to DAG, fatty acids (FA), monoacylglycerol (MAG), or triacylglycerol (TAG) was incorporated into liposomes followed by determination of the integration activity (Fig. 2). Because the integration activity for Pf3 coat was essentially the same as that for M13 (H5) procoat (Fig. 1, A and  B; data not shown), M13 H5 procoat was hereafter used as a representative potential-dependent substrate. The integration activities for both M13 H5 procoat and 3L-Pf3 coat with lipo- Liposomes were formed from polar phospholipids supplemented with (PLϩDAG) or without (PL) 1,2-dioleoyl-sn-glycerol. After in vitro synthesis in the presence of the indicated membranes, the integration activities were determined by proteinase K (PK) digestion. The full-length translation products and their membrane protected fragments (MPF) that reflect membrane integration are indicated by arrows. 50% of each translation product was analyzed. DCCD was added to dissipate PMF. The integration efficiency was quantitated, as indicated. somes containing either FA or MAG were the same as those with liposomes composed of polar phospholipids only (Fig. 2). On the other hand, liposomes with TAG exhibited almost no integration activity toward either protein, as did ones with DAG (Fig. 2). Because both DAG and TAG were similarly effective for the blockage of spontaneous integration, liposomes with various amounts of DAG or TAG were prepared followed by determination of their integration activities (Fig. 3). With increasing the DAG or TAG amounts in liposomes, the integration activities for M13 H5 procoat (Fig. 3A) and 3L-Pf3 coat (Fig. 3C) decreased. Essentially, the integration of both membrane proteins was completely blocked when 3% or more DAG was included. In the case of TAG the blockage was significant even with 1% for both membrane proteins. When the integration activity was plotted as a function of the DAG or TAG amount (Fig. 3, B and D), it was found that blockage by TAG is slightly more effective than that by DAG. Although spontaneous integration is blocked by TAG efficiently, liposomes with TAG exhibit defective integrity of the bilayer structure (see Fig.  8). From these findings it was concluded that the blockage of spontaneous integration is specific to DAG.
Mechanism Underlying the Blockage of Spontaneous Integration by DAG-To clarify what property of DAG is needed for the blockage of spontaneous integration, we examined whether various kinds of DAG or DAG derivatives have the ability to block spontaneous integration. In Fig. 4, the effect of the length of acyl chains in DAG was examined. The structures of DAG derivatives used here are shown in Fig. 4A. Liposomes containing DAG with diheptanoyl residues (C7) or shorter acyl chains exhibited the same integration activities as ones without DAG for both M13 H5 procoat (Fig. 4B) and 3L-Pf3 coat (Fig. 4C). In marked contrast, DAG with dioctanoyl residues (C8) or longer acyl chains completely blocked spontaneous integration (Fig. 4, B and C). When the integration activities were plotted as a function of the length of acyl chains (Fig. 4D), it became evident that the acyl chain of C8 is a critical length for blocking of spontaneous integration.
It is known that all DAG expressed in vivo is of type 1, 2-DAG (33). Therefore, another form of DAG, 1, 3-DAG (Fig. 5A), was examined. We found that this form of DAG was as effective for the blockage of spontaneous integration as physiological DAG (Fig. 5, B and C), indicating that the second acyl chain attached to MAG can be at either the 2 or 3 position.
In the experiments depicted in Fig. 4 we used DAG with two identical acyl chains. Next, we examined DAG with dissimilar acyl chains, 1-oleoyl-2-acetylglycerol (1-O-2-A) (Fig. 5A). Although the number of C atoms for acetyl and oleoyl residues is 20 and bigger than that for dioctanoyl residues (8 ϫ 2), this DAG was unable to block the spontaneous integration of both M13 H5 procoat and 3L-Pf3 coat (Fig. 5, B and C), suggesting that the total hydrophobicity itself is not critical for the blockage of spontaneous integration.
Phosphatidic acid, a DAG derivative with a phosphate residue (Fig. 5A), was also examined. It was found that this additional phosphate still allowed 50% spontaneous integration of both M13 H5 procoat and 3L-Pf3 coat when compared with liposomes without DAG (Fig. 5, B and C). Thus, phosphatidic acid is not a sufficient lipid for blocking of spontaneous integration.
In these experiments we used liposomes prepared by sonication, the size of which is small (20ϳ50 nm) (34). To examine whether the highly curved nature of the bilayer structure affects the efficiency of spontaneous integration, we prepared large liposomes by means of an extruder and compared the spontaneous integration of 3L-Pf3 coat with those sonicated. As illustrated in Fig. 6, the integration activity of 3L-Pf3 coat was essen-tially the same between the large and small liposomes in the presence and absence of DAG, strongly suggesting that the blockage of spontaneous integration by DAG was not caused simply by changes in the membrane curvature or the lateral pressure.
In summary, to block spontaneous integration, the hydrophobic property of DAG is important, as an additional phosphate residue negatively affects the ability to block spontaneous integration. However, the bulky structure of DAG is needed rather than the total hydrophobicity, as seen for 1-oleoyl-2acetylglycerol. The change in the extent of membrane curvature does not seem to underlie the blockage of spontaneous integration by DAG.
Determination of DAG Content in E. coli-The DAG content of wild type E. coli cells has been reported to be ϳ0.06-ϳ1.3% that of total phospholipids (31,35). We repeated the determination of the DAG content in a solvent-extracted lipid mixture according to previous reports. However, it yielded high variability ranging from 0.1% to even 6%, suggesting that both DAG and phospholipids could not quantitatively be extracted under these conditions. Therefore, we extracted total lipids by detergents from cells uniformly labeled with [ 14 C]palmitate. We used Triton X-100 to extract lipids, as DAG is quantitatively solubilized by the detergent (36). The DAG content of MC4100 was now reproducibly determined to be ϳ1.5% (Table 1), which when present in liposomes showed a significant effect on the blockage of spontaneous integration (see Fig. 3).
Several gene products are known to produce DAG. The genes are eptB (37), mdoB (38,39), and pgpB (40 -42). To reveal the significance of DAG in vivo, we knocked out these genes in  MC4100. However, the individual knockouts (YK01, YK02, and YK03) expressed DAG at a similar level as MC4100 (Table 1). Even the triple knock-out, YK2301, expressed DAG at a similar level ( Table 1). The dgkA gene encodes a DAG kinase, which produces PA at the expense of DAG. In the ⌬dgkA knock-out (JWK4002), the DAG content, therefore, was significantly increased (Table 1) as reported (31,35). Plasmid pTD1, an overproducer of DgkA, reduced the DAG content of the ⌬dgkA strain (Table 1, JWK4002/pTD1), indicating that this plasmid expresses the functional DgkA. When pTD1 was induced either in MC4100 or in the triple knock-out (YK2301), the DAG content was not affected at all (Table 1). These results indicate that the DAG content is strictly regulated in the cell, supporting the importance of DAG in vivo.
Depletion of Both DAG and the Integration-stimulating Factor Partially Restores Spontaneous Integration of 3L-Pf3 Coat-To confirm that the blockage of spontaneous integration by DAG observed in liposome studies is indeed operative in native INVs, we reconstituted proteoliposomes depleted of DAG by the DgkA function. INVs were first treated with urea and cholate to remove the integration-stimulating factor that is always present in E. coli (19). The urea/cholate-treated INVs were then solubilized with octylglucoside followed by incubation with ATP. It was expected that DAG would be converted to PA if the solubilized membrane proteins contained sufficient DgkA. Proteo-liposomes were reconstituted after ATP treatment without adding exogenous lipids (Fig. 7A). When DAG-overexpressing INVs (JWK4002) or triple-knock-out INVs (YK2031) were used as starting material, the spontaneous integration of 3L-Pf3 coat into the resulting proteoliposomes remained blocked irrespective of the ATP incubation (Fig. 7B). Note that these proteoliposomes also contain YidC because YidC is not removed by the urea/cholate extraction (19). In contrast, when DgkA-overproducing INVs (YK2301/pTD1) were treated with ATP, 3L-Pf3 coat integration increased significantly (Fig. 7B). Although the integration activity was still low (ϳ5%), this increase was dependent both on ATP-treatment and on overproduction of DgkA, indicating that DAG depletion in proteoliposomes partially restores spontaneous integration. The partial restoration is presumably due to the fact that PA by itself has a weak ability to block spontaneous integration (see Fig. 5).
3L-PF3 Coat Integration Is Dependent on the Integrationstimulating Factor but Is Deficient in TAG-containing Liposomes-Because 3L-Pf3 coat was found not to be spontaneously integrated into both liposomes and native INV-derived proteoliposomes, we examined if 3L-Pf3 coat integration depends on the lipid A-derived integration-stimulating factor, as does M13 procoat integration (19). Proteoliposomes con-  To remove the integration-stimulating factor, INVs were treated with 6 M urea and 6% sodium cholate as described (19). The urea/cholate-washed INVs were solubilized by buffer A containing 1.5% octylglucoside followed by incubation either with 5 mM ATP, 5 mM MgSO 4 or with 5 mM MgSO 4 for 1 h at 37°C. The ATP-treated solubilized membranes were dialyzed against buffer A to form proteoliposomes. The reconstituted proteoliposomes were then recovered as described under "Experimental Procedures." B, the integration activity of 3L-Pf3 coat into the proteoliposomes (250 g of membrane proteins/ ml) reconstituted as described in A using INVs prepared from the indicated strain was determined. YK2301 (⌬eptB ⌬mdoB ⌬pgpB)/pUSI2 and YK2301/ pTD1 (Ptac-dgkA) were cultivated in the presence of 1 mM isopropyl 1-thio-␤-D-galactopyranoside. The solubilized membrane proteins were treated with or without ATP as indicated. taining DAG and the factor indeed showed integration activity toward M13 H5 procoat (Fig. 8A), as reported (19). These proteoliposomes were also active as to 3L-Pf3 coat integration (Fig.  8B), indicating that the potential-independent membrane protein is also integrated in an integration factor-dependent manner. Therefore, it is concluded that 3L-Pf3 coat integration does not occur spontaneously but depends on the integration factor. TAG was found to be a more effective lipid for the blockage of spontaneous integration than DAG (see Figs. 2 and 3). Therefore, we examined the effect of TAG on integration factor-dependent integration (Fig. 8). Both types of membrane proteins were not integrated into proteoliposomes containing TAG even if the integration factor had been co-reconstituted (Fig. 8). The recoveries of the factor in both types of proteoliposome preparations were almost the same (data not shown). These results strongly suggest that liposomes containing TAG exhibit defective membrane integrity that not only blocks spontaneous integration but also the integration factor-dependent integration, although TAG has a higher ability to block spontaneous integration.

DISCUSSION
Spontaneous integration into liposomes has long been thought to occur and, thus, to be one of the mechanisms underlying protein integration into membranes, especially of M13 procoat and Pf3 coat (7,8). Upon the discovery of YidC, M13 procoat was revealed not to be spontaneously integrated, as YidC depletion caused a severe defect in M13 procoat integration (9). Moreover, it has been reported that the integration of Pf3 coat into liposomes is stimulated by purified YidC (10). However, its potential-independent derivative, 3L-Pf3 coat, has been shown to be still integrated into YidC-deficient liposomes, suggesting a spontaneous mode of integration (10). We demonstrated that even the spontaneous integration of 3L-Pf3 coat is specifically blocked by a physiological non-bilayer lipid, DAG.
To clarify the mechanism underlying the blockage of spontaneous integration, we examined the effects of various lipids on the integration activity. The length of acyl chains was critical and should be eight or longer for the blockage. Moreover, the attachment of a phosphate residue to DAG (PA) restored spontaneous integration to half the full level. Therefore, the hydrophobic property of DAG turned out to be important for the blockage. However, 1-oleoyl-2-acetylglycerol, which possesses more C atoms than dioctanoylglycerol, was unable to block spontaneous integration, as were MAG and FA. These observations indicate that a certain threshold hydrophobicity is not sufficient for the blockage. Instead, two acyl chains of a certain length should be attached to the glycerol backbone. Therefore, it is likely that the bulky structure of DAG is essential for the blockage. On the surface of liposomes, the hydrophilic heads of phospholipids are likely to be positioned sufficiently far apart to allow the formation of open conical spaces inside the bilayer leaflets. The structure with these open spaces would be thermodynamically unstable and, therefore, provide a lipophilic force, allowing spontaneous integration of membrane proteins. The bulky structure of DAG may be suitable to fill such open spaces in the lipid bilayers of liposomes and, thus, to seal the membranes. Simple hydrophobic compounds such as FA, MAG, and DAG with short acyl chains would not form a sufficiently bulky structure to fill the spaces. This idea is consistent with the observation that TAG was more efficient than DAG for the blockage of the spontaneous integration. However, liposomes containing TAG could not support the lipid A-derived integration-stimulating factor-dependent reaction, suggesting that the membrane integrity was compromised when TAG is present in the liposomes. These results also explain why E. coli expresses DAG but not TAG (31). It is known that DAG affects the lateral pressure of the membrane (43). However, because large liposomes showed essentially the same effects of DAG on the efficiency of spontaneous integration as the sonicated and small ones, it is not simply a change in membrane curvature and, therefore, in the lateral pressure, which would explain the blockage of spontaneous integration by DAG.
In the presence of DAG, when no spontaneous integration occurs, the integration of all the Sec-independent substrates, including 3L-Pf3 coat, was found to depend on the lipid A-derived integration-stimulating factor. Moreover, proteoliposomes reconstituted from native INVs, which contain YidC but not the integration-stimulating factor, revealed no integration activity even for 3L-Pf3 coat. Therefore, YidC was dispensable for integration. It has been reported that YidC depletion causes a great reduction of PMF (3). Indeed, ⌬YidC INVs were deficient in the generation of PMF (data not shown), which should cause the inhibition of integration of potential-dependent substrates. On the other hand, it has been reported that the integration of some potential-independent version of M13 procoat and Pf3 coat is also affected by YidC depletion (13,14). Because our integration assay relies on the proteinase K protection of the membranes, early steps of integration are likely to be those being analyzed. Late steps of integration, such as the completion of integration, might not be reflected. Consistently, M13 procoat is resistant to alkaline extraction even after YidC depletion (14), indicating that the initial step of integration does not FIGURE 8. 3L-PF3 coat integration is dependent on the integration-stimulating factor but is deficient in TAG-containing liposomes. The integration-stimulating factor was reconstituted using liposomes containing either 1,2-dioleoyl-sn-glycerol (DAG) or trioleoylglycerol (TAG). M13 H5 procoat (A) and 3L-Pf3 coat (B) were in vitro synthesized in the presence of liposomes or proteoliposomes with the integration factor, as indicated. The integration efficiency was determined as shown in the legend to Fig. 1, as indicated.
need the assistance of YidC. Also, in the case of MtlA integration, YidC was not involved in the integration, as revealed by the appearance of a membrane-protected fragment (19), although the integration intermediates of nascent chains of MtlA can be efficiently cross-linked with YidC (44). It has been proposed that YidC acts as a membrane insertase for Sec-independent proteins as Pf3 coat integration was found to be stimulated by YidC. However, under those experimental conditions spontaneous integration into liposomes devoid of YidC could still have occurred (10) due to the lack of DAG. Moreover, 3L-Pf3 coat was very efficiently integrated independently of YidC (10). Here we show that 3L-Pf3 coat is not integrated into liposomes when spontaneous integration is blocked by DAG and that correct reconstitution of its membrane integration requires the presence of a lipid A-derived integration factor. These findings indicate that this integration-stimulating factor is important as a membrane protein integrase.
The DAG content in vivo seems to be strictly regulated, as the combination of gene disruption of three genes (mdoB, eptB, and pgpB) and DgkA overproduction did not cause any significant decrease in DAG content. Especially, it has been suggested that DAG synthesis by the mdoB gene, which is involved in biosynthesis of the membrane-derived oligosaccharides, is a major pathway in E. coli (31). Moreover, the DAG concentration, which gave significant blockage of spontaneous integration, was similar to that of wild type cells. Indeed, in native INVderived proteoliposomes, in which DAG was converted to PA by preincubation with ATP and DgkA before reconstitution, spontaneous integration was partially restored, indicating that the blockage of spontaneous integration by DAG also occurs in native INVs. Considering that some lipids, such as PA, also have an ability to reduce spontaneous integration but that their content is comparably low, it is highly likely that DAG plays an important role other than being the precursor of phospholipids.