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© The Rockefeller University Press, 0021-9525/2000//413 $5.00
The Journal of Cell Biology, Volume 151, Number 2, , 2000 413-424

Evidence That the Transition of HIV-1 Gp41 into a Six-Helix Bundle, Not the Bundle Configuration, Induces Membrane Fusion

^a Department of Molecular Biophysics and Physiology, Rush Medical College, Chicago, Illinois 60612
^b Trimeris Inc., Durham, North Carolina 27707
Department of Molecular Biophysics and Physiology, Rush Medical College, 1653 W. Congress Parkway, Chicago, IL 60612.(312) 942-8711(312) 942-6753

Many viral fusion proteins exhibit a six-helix bundle as a core structure. HIV Env–induced fusion was studied to resolve whether membrane merger was due to the transition into the bundle configuration or occurred after bundle formation. Suboptimal temperature was used to arrest fusion at an intermediate stage. When bundle formation was prevented by adding inhibitory peptides at this stage, membranes did not merge upon raising temperature. Inversely, when membrane merger was prevented by incorporating lysophosphatidylcholine (LPC) into cell membranes at the intermediate, the bundle did not form upon optimizing temperature. In the absence of LPC, the six-helix bundle did not form when the temperature of the intermediate was raised for times too short to promote fusion. Kinetic measures showed that after the temperature pulse, cells had not advanced further toward fusion. The latter results indicate that bundle formation is the rate-limiting step between the arrested intermediate and fusion. Electrical measures showed that the HIV Env–induced pore is initially large and grows rapidly. It is proposed that bundle formation and fusion are each contingent on the other and that movement of Env during its transition into the six-helix bundle directly induces the lipid rearrangements of membrane fusion. Because peptide inhibition showed that, at the intermediate stage, the heptad repeats of gp41 have become stably exposed, creation of the intermediate could be of importance in drug and/or vaccine development.

Key Words: fusion pore • fusion intermediates • inhibitory peptides • fusion kinetics • hemifusion

© 2000 The Rockefeller University Press

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

 
It has been observed that many viral fusion proteins share a common crystallographic structure: a six-helix bundle with each monomer of a trimer set in a hairpin bend (Skehel and Wiley 1998). This observation leads to the possibility that many fusion proteins induce fusion by essentially the same mechanism. The Env protein of HIV is among the class of proteins that form six-helix bundles.

HIV Env is a trimer, with each monomer consisting of two subunits, gp120 and gp41 (Skehel and Wiley 1998; Wyatt and Sodroski 1998). gp120 binds to a CD4 receptor on target membranes and undergoes conformational changes that allow gp120 to then interact with chemokine receptors, the coreceptors on the target membrane (Berger et al. 1999). A cascade of conformational changes ensues, culminating in gp41 inducing fusion of the viral envelope with the plasma membrane, thereby initiating infection. Each gp41 contains an NH₂-terminal leucine/isoleucine heptad repeat (HR) segment (HR1; Fig. 1) that has been crystallographically shown to form a central triple-stranded -helical coiled coil core (Chan et al. 1997; Weissenhorn et al. 1997). The coiled coil creates highly conserved grooves that are transiently exposed during the fusion process (Chan and Kim 1998; Furuta et al. 1998; Munoz-Barroso et al. 1998). Exposure permits a COOH-terminal HR segment (HR2; Fig. 1) to pack into the grooves in an antiparallel orientation, forming the core gp41 configuration; at this point, HR1 and HR2 do not undergo any further conformational changes and a six-helix bundle with each gp41 in a hairpin bend has been created.

View larger version (12K): [in this window] [in a new window] [Download PPT slide]   Figure 1 Schematic of location of HR1 and HR2 within HIV-1 gp41 and the hairpin bend of a monomer within a six-helix bundle. FP, NH2-terminal fusion peptide; TM, transmembrane domain.

Membrane merger is the central and defining event of fusion. In viral fusion, it has often been assumed that the six-helix bundle forms before fusion and serves to bring the membranes into close apposition (Weissenhorn et al. 1997; Chan and Kim 1998). An alternate possibility, however, is that the free energy released as fusion proteins reconfigure into the six-helix bundle induces fusion, and by the time the bundle has formed, fusion pores have resulted (Baker et al. 1999). It is pivotal to pinpoint the role of the six-helix bundle in fusion to understand the process of membrane merger, but direct determination of the precise order of events is difficult because the lipid and protein rearrangements during fusion are transient and local. We devised an experimental approach to determine the temporal order of formation of the six-helix bundle and the fusion pore based on the following logic: if the six-helix bundle itself causes fusion, the bundle must be able to form before fusion pore formation; if the bundle cannot form before the membranes fuse, it cannot be the cause of merger. Through this approach we demonstrate that for HIV Env protein the six-helix bundles do not form before membrane fusion. Therefore, fusion is caused by the movement of protein into the six-helix bundle rather than by the six-helix bundle itself.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

 
Materials
Soluble CD4 (sCD4, from Dr. R. Sweet, SmithKline Beecham, Department of Surgical Biology, King of Prussia, PA) and anti-CD4 mAb Q4120 (from Dr. Q. Sattentau, Centre d'Immunologie de Marseille-Luminy, Marseillle, France; Healey et al. 1990) were obtained through the AIDS Research and Reference Reagent Program, Division of AIDS, National Institute of Allergy and Infectious Diseases, National Institutes of Health. All fluorescent dyes were purchased from Molecular Probes, Inc. Oleic acid (OA), stearoyl-lysophosphatidylcholine (LPC), BSA, and poly-L-lysine were purchased from Sigma-Aldrich. The T22 peptide was obtained from Bachem Bioscience. To inhibit fusion between cells, we used the peptides T20 (corresponding to residues 643–678 of gp41) and T21 (residues 558–595). T20 and T21 (also known as DP178 and DP107, respectively) were synthesized as described previously (Lawless et al. 1996). The purity of the peptides was determined by analytical HPLC to be >95%. Concentrations of stock solutions containing the peptides were measured by the method of Edelhoch 1967.

Maintenance and Fluorescent Labeling of the Cells
TF228.1.16 cell line constitutively expressing gp160 of the T-tropic BH10 strain of HIV-1 (Jonak et al. 1993) was a gift from Dr. Z.L. Jonak (SmithKline Beecham, Philadelphia, PA). These cells, designated as effector cells, were grown in RPMI 1640 supplemented with 10% FBS (both from GIBCO BRL). The HelaT4+ cells expressing CD4 and chemokine receptor (CXCR4) (Maddon et al. 1986) were obtained through the AIDS Research and Reference Reagent Program. HelaT4+ cells were maintained in DMEM (GIBCO BRL) supplemented with 10% Cosmic^TM serum (HyClone Laboratories) and 0.5 mg/ml of geneticin (GIBCO BRL) and were used as target cells for fusion experiments. The effector and target cells were labeled essentially as described (Munoz-Barroso et al. 1998; Melikyan et al. 2000). In brief, 4 x 10⁶ TF228 cells/ml were labeled with 1.3 µM calcein AM. HelaT4+ cells (2 x 10⁶) were colabeled with 30 µM of the cytoplasmic marker 7-amino-4-chloromethylcoumarin (CMAC) and, when required, with 15 µg/ml of the membrane dye 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI).

Fluorescence Microscopy Assay for Cell–Cell Fusion and Use of Inhibitory Agents
The fluorescently labeled effector and target cells were bound to each other in one of two ways. In the first protocol, 7–10 x 10⁴ of both target and effector cells were mixed together in small microfuge tubes containing 0.2 ml of Hepes-buffered DMEM (pH 7.2) supplemented with 1 mg/ml of BSA and transferred into the wells of an 8-chambered glass slide (Lab-Tek^®; Nunc) that was precoated with poly-L-lysine. The precoating allowed the cells to quickly and efficiently adhere to the glass and establish side by side contacts with each other. Side by side placement facilitated identification of bound cells and quantification of dye spread. In the second protocol, 8 x 10⁴ target HelaT4+ cells per well were grown overnight, to 80–90% confluency, on noncoated glass in the 8-chambered slides. Cells were then loaded with CMAC but could not, as a practical matter, be labeled with DiI. About 2 x 10⁵ effector TF228 cells were placed on top of the flattened target cells, and within 30 min the effector cells had adhered sufficiently well that they were not removed by multiple washings. This procedure yielded an 1:1 ratio of target to effector cells. The second protocol was used whenever the fusion-inhibitory peptide T20 had to be removed by washing. (T20 bound to both the uncoated and polylysine-coated glass slide and could not be effectively washed out, whereas T21 was efficiently removed from coated glass by washing.) Using the second protocol, both T20 and T21 were efficiently removed from the chamber by washing. For both protocols, once effector and target cells were bound to each other, the chambered slides were either incubated for 3 h at 22–24°C in the dark, followed by a 30–45-min incubation at 37°C or the temperature was immediately raised to 37°C and maintained for 2 h.

The extent of fusion was assessed by visual microscopic examination. As required, the fluorescence images were captured with an intensified (KS1380; Video Scope) CCD video camera (model 72; Dage-MTI, Inc.), were recorded on S-VHS format videotape, and the images were analyzed off-line (Qiao et al. 1999). Images of fluorescent cells were acquired separately for each fluorescent dye, digitized, and pseudocolored according to their emission wavelength. For cells bound to polylysine-coated glass, three images were then superimposed to detect whether fluorescent dyes had redistributed; fused cells had a lighter (pinkish) appearance. Cells partially overlapping in the bound state also present a lighter appearance, but are readily distinguishable from cells that have actually fused. The fraction of effector and target cells in contact that became stained with all 3 dyes (screening >100 cell pairs per well) provided the extent of fusion (Melikyan et al. 2000). For example, 50% of the contacting cells have fused in Fig. 2 B. When effector cells were placed upon target cells grown on untreated glass, the two images (one for each aqueous dye) were superimposed. The extent of fusion was quantified as the number of target cells that acquired calcein (from the effector cells) normalized by the total number of target cells in the field of view. When high-time resolution kinetic measurements for the onset of calcein spread between effector and target cells were required, a temperature jump (T-jump) technique was used (see below) to determine the cells that fused within 5 min of raising temperature (20% of the total cell pairs).

View larger version (62K): [in this window] [in a new window] [Download PPT slide]   Figure 2 A three-color fluorescent assay of fusion. The cells were adhered to polylysine-coated glass. Effector cells are green (calcein) and target cells are purple (a mixture of the red DiI and the blue CMAC). Fused cells are pinkish. (A) Fusion did not occur at TAS. (B) After raising the temperature to 37°C for 30 min, fusion occurred and all three dyes redistributed (arrowheads).

Inducing Rapid Increases in Temperature
We employed a water-cooled Peltier device (20/20 Technology) to maintain the temperature in the experimental chamber between 4°C and 37°C. A T-jump, an increase of temperature of a small volume (1 µl) of the chamber, was achieved by illuminating with an infrared (IR) laser diode (Opto Power Corp.) as described (Melikyan et al. 2000). To selectively heat a cell pair of interest and its surrounding volume, we mounted IR-absorbing glass to the bottom of the experimental chamber. Cells were placed on the IR-absorbing glass, and a cell pair was positioned in the center of illumination of the fixed laser beam. The temperature of the solution immediately bathing an illuminated cell was determined by measuring the changes in the resistance of a second patch pipette manipulated within 10 µm of the cell. The changes of the pipette resistance were converted into temperature with use of a calibration curve obtained from the relation between the pipette resistances and temperatures of a bulk solution in the temperature-controlled chamber. A steady state temperature was established within 2–4 s upon illumination. We validated the use of pipette resistance by using hydrocarbons with known melting temperature. A steady state temperature of 37°C achieved by IR illumination, according to pipette resistance, melted eicosane (melting point 36–38°C; Sigma-Aldrich), but not henecosane (melting point 40–42°C), over an area with diameter 300 µm.

Electrical Measurements of the Fusion Pore
A coverslip with cells at TAS was transferred into a chamber and maintained at 12–14°C. The effector cells were patch clamped in the whole-cell mode, and time-resolved admittance (i.e., "capacitance") measurements were performed and pore conductance was calculated as described previously (Melikyan et al. 1999; Qiao et al. 1999). Cell–cell fusion was triggered by quick, local increase of temperature to 37°C by our T-jump method. Average conductances were determined by aligning pores at their moment of opening and calculating the mean pore conductance every 5 ms. Pore conductance was converted to approximate pore diameter by using the conductivity of the bulk solutions and assuming a pore length of 15 nm.

Online Supplemental Material
Supplemental figures are supplied in which both the images (Figure S1) and the graphs (Figure S2) demonstrate that if T20 or T21 blocked pore formation, it also blocked lipid dye transfer. All supplementary materials are available at http://www.jcb.org/cgi/content/full/151/2/413/DC1.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
We used a suboptimal temperature to arrest fusion at an intermediate stage preceding (i.e., upstream of) lipid mixing and pore formation. Our strategy was to arrest the fusion process as close as we could to the point of pore formation and then manipulate conditions from this stage in order to separate six-helix bundle formation and membrane merger from a multitude of prior steps. We showed that when temperature was subsequently increased, the intermediate proceeded on to fusion. We tested for bundle formation at the temperature-arrested intermediate with peptides that inhibit fusion when they bind to the grooves on the surface of the central coiled coil core (T20, also known as DP178) and to HR2 (T21, also known as DP107). Whether the bundle could still form when lipid merger was prevented was tested by inserting LPC into membranes after establishing the intermediate and then raising the temperature. We also tested in another manner (without the need to add exogenous lipid) whether the six-helix bundle might form before the creation of a fusion pore by examining whether temperature increases maintained for short times could induce bundle formation without causing fusion. The relation between bundle formation and membrane merger could be determined by this logical design of experiments, whichever temporal sequence proved to be the case.

Creating a Temperature-arrested Intermediate of Fusion
We used a stable cell line constitutively expressing an HIV Env (from BH10 strain) that requires CXCR4 chemokine receptors on CD4⁺ target cells in order for fusion to occur. Calcein-labeled Env-expressing cells (we define these as effector cells) and CD4⁺/CXCR4⁺ target cells labeled with DiI and CMAC were plated onto polylysine-coated glass, or alternatively, the effector cells were laid on top of target cells that had been grown overnight and then fluorescently labeled with CMAC. We used the temperature sensitivity of Env-induced fusion (Frey et al. 1995; Hart et al. 1996) to arrest fusion at an intermediate stage. Cells maintained at 23°C showed neither aqueous nor membrane dye transfer (Fig. 2 A) even up to 5 h. However, upon raising the temperature to 37°C, both aqueous and membrane dye mixed efficiently (Fig. 2 B). We refer to the stage reached after maintaining 23°C (usually for 3 h) as the temperature-arrested stage, TAS, of fusion.

To establish a reference to which TAS could be compared, cells were maintained at 37°C and at a set time were placed on ice to stop further fusion activity. (In control experiments, we verified that this method did arrest further fusion: dye did not spread between additional cells for 1 h after lowering the temperature to 4°C; not shown.) After fusion was stopped, the kinetics of fusion was obtained by microscopically counting the percentage of cell pairs that had exchanged fluorescent dye at a given time (Fig. 3 A, open squares). Fusion was slow: a significant lag time, 15–20 min (in agreement with previous studies; Frey et al. 1995; Weiss et al. 1996), preceded the onset of dye spread, and it took 2 h to reach its maximum extent.

View larger version (22K): [in this window] [in a new window] [Download PPT slide]   Figure 3 (A) The fraction of cells in contact that fuse as a function of time at 37°C. Cells were either coincubated directly at 37°C (), or TAS () or 4°-TAS () was first established and temperature was then raised to 37°C. Error bars show the standard error of four to eight experiments. (B) The ability of agents to block fusion through binding to gp120, CD4, or CXCR4. In control experiments (first bar), TAS was created and temperature was then brought to 37°C for 45 min. sCD4, a neutralizing antibody against CD4 (Q4120), or a peptide that binds to CXCR4 (T22) were added either at the beginning of coincubating the effector and target cells for 3 h at 23°C (23°C, cross-hatched bars) or after establishing TAS by a 2-h coincubation and then allowing 1 h at 23°C for the agents to bind (black bars). Alternatively, the inhibitory agents were added either before (4°C, cross-hatched bars) or after a 2-h coincubation (establishing 4°-TAS) of cells at 4°C (black bars). The extent of fusion was normalized by the control experiments without inhibitory agents. The concentrations of the agents were: 50 µg/ml of sCD4, 40 µg/ml of Q4120, and 20 nM of T22 peptide.

Membrane and Protein Conformational Changes En Route to TAS
Although the fusion process had been advanced by creating TAS, lipid mixing had not yet occurred (Fig. 2 A). Adding 0.5 mM chlorpromazine (known to promote fusion between hemifused pairs of influenza virus hemagglutinin (HA)-expressing cells and erythrocytes; Melikyan et al., 1997; Chernomordik et al., 1998) at the point of TAS did not promote lipid or aqueous content mixing (not shown). The complete absence of lipid dye spread even after the addition of chlorpromazine shows that hemifusion most probably has not been established at TAS.

We assessed how far gp120/gp41 has proceeded toward fusion by the point of TAS. Adding sCD4, or an mAb against CD4 that competes with gp120 binding (Q4120), or a peptide (T22) that binds to CXCR4, at the start of coincubating the effector and target cells at 23°C strongly suppressed Env-mediated fusion (Fig. 3 B, cross-hatched bars, 23°C). The results we found in this control were as expected, because these agents are known to protect against infection by HIV-1 and inhibit Env-induced cell–cell fusion (Healey et al. 1990; Endres et al. 1996; Murakami et al. 1999). However, sCD4 and Q4120 inhibited fusion much less when added at TAS (Fig. 3 B, black bars, 23°C), demonstrating that either TAS is a post–CD4-binding stage or the binding sites of CD4 and/or gp120 become less accessible. Adding T22 at TAS inhibited fusion more effectively than did sCD4 or Q4120, but not as well as when added before TAS. This indicates that CXCR4-dependent steps may not have been completed or the association between gp120 and the coreceptor is still reversible (Doranz et al. 1999) at TAS. When effector and target cells were maintained at 4°C for 3 h to create 4°-TAS, all three agents abolished fusion regardless of whether they were added at the onset of the coincubation (cross-hatched bars, 4°C) or at 4°-TAS (black bars, 4°C). The greater inhibition by each of these agents at 4°-TAS than at TAS demonstrates that 4°-TAS is upstream of TAS and has not significantly advanced in the fusion process; this is in agreement with the kinetic measurements (Fig. 3 A).

The HRs of gp41 Are Stably Exposed at TAS
The peptides T20 and T21 cannot bind to either the native structure of gp41 or the final six-helix bundle; they can only bind to an intermediate conformation(s) of gp41 (Chen et al. 1995; Furuta et al. 1998; Kliger and Shai 2000). When T20 or T21 was added to effector cells at 23°C (in the absence of target cells) and then unbound peptides were washed away, fusion was not inhibited when the effector cells were subsequently bound to target cells (grown on glass slides) and the temperature was raised to 37°C (Fig. 4 A, second and fourth bars). Neither CD4 nor CXCR4 was present when the peptides were added to effector cells, and as expected gp41 remained in its native state. For many strains (including BH10), binding sCD4 to gp120 is sufficient to expose the grooves created by HR1 to T20, and HR2 to T21 (Furuta et al. 1998). We refer, for convenience, to states of HIV Env that will allow T20 and T21 to bind as "activated." For our system, adding the peptides to effector cells (again, without target cells) in the presence of sCD4 at 23°C significantly inhibited subsequent fusion to the target cells after the sCD4 and unbound peptides were washed away (Fig. 4 A, third and fifth bars). We showed that this inhibition was caused by binding of the peptides rather than by sCD4-induced shedding of gp120 or other adverse effects: adding (and then washing out) a high concentration of sCD4 alone to effector cells did not suppress fusion to target cells (Fig. 4 A, sixth bar). Thus, sCD4 alone is sufficient to activate gp41 at 23°C.

View larger version (35K): [in this window] [in a new window] [Download PPT slide]   Figure 4 Using T20 and T21 to assess formation of six-helix bundles. (A) T20 and T21 inhibit fusion after sCD4 binding in the absence of target cells. Effector TF228 cells were treated with agents as indicated and the agents were removed by washing; the effector cells were then bound to target HelaT4 cells grown on untreated glass, and fusion was measured after raising temperature to 37°C for 2 h. When adding T20 and T21 to effector cells alone, fusion occurred to the same extent as for the control (first bar). Adding sCD4 alone did not affect fusion (sixth bar), but the addition did expose the HRs to T20 (third versus second bar) and T21 (fifth versus fourth bar). The peptides and sCD4 were added simultaneously. (B) T20 and T21 inhibited fusion after creating TAS and the peptides remained bound to gp41 for long times. Effector cells were laid on top of target cells grown on slides and TAS was created. After a mock wash (without adding peptides), raising temperature to 37°C for 30 min led to fusion (first bar). (The extent of fusion was the same when the mock wash was omitted.) Adding T20 or T21 after TAS was created abolished fusion (second and third bars). Fusion was significantly reduced even after washing out unbound T20 or T21 and immediately raising temperature to 37°C (fourth and fifth cross-hatched bars). Raising temperature 1 h after washing led to a greater, but still significantly impeded, extent of fusion (white bars above cross-hatches). In control experiments, T20 or T21 (black bars) were incubated for 1 h at 23°C with target cells grown on slides, the unbound peptides were removed by washing, the effector cells were bound, and temperature was raised to 37°C for 2 h, fusion was not inhibited. The concentrations of agents were: 50 µg/ml of sCD4, 40 nM T20, and 220 nM T21.

We found that if T20 and T21 blocked pore formation, they also abolished lipid dye mixing. That is, for all concentrations of inhibitory peptides, they always blocked the process before any lipid dye spread (see Figures S1 and S2 at http://www.jcb.org/cgi/content/full/151/2/413/DC1), which would have signaled hemifusion of cell membranes. (This contrasts to the findings of Munoz-Barroso et al. 1998, who reported that low concentrations of T20, but not T21, blocked aqueous dye mixing while still permitting lipid dye transfer.) Hemifusion is the merger of outer monolayer membrane leaflets with the inner leaflets contacting each other to form a hemifusion diaphragm that continues to separate aqueous contents.

The Formation of the Six-Helix Bundle Requires Membrane Merger
Preventing Membrane Merger with LPC Abolishes Bundle Formation.
LPC inhibits fusion in a wide variety of systems by preventing the merger of contacting lipid monolayer leaflets of membranes (i.e., hemifusion). It is thought to do so because of its positive spontaneous curvature (Chernomordik et al. 1995). Whether or not hemifusion does indeed occur before fusion, in general LPC arrests fusion at the point of membrane merger (Chernomordik et al. 1998) as a lipid constituent of membranes and not by binding to proteins. Stearoyl-LPC (LPC) is particularly useful because it is sufficiently hydrophobic to remain in membranes after any LPC still in solution is removed, or, if necessary, it can be removed from the membranes with a BSA wash (Chernomordik et al. 1997). We added LPC after TAS was established and removed the unbound fraction, using cells labeled with only aqueous dyes so that lipid composition would not be affected by incorporation of lipid dyes. Temperature was raised to 37°C for 15 min, by which time the majority of cell pairs would have fused if LPC had not been added (Fig. 3 A). We then lowered temperature to 23°C, and found that pore formation was meager (Fig. 5 A, second bar). We refer to the stage reached after lowering temperature back to 23°C as a lipid-arrested stage (LAS) of fusion (Fig. 5 A, inset). Fusion still did not occur when the membrane-bound LPC was removed at the point of LAS (data not shown). But fusion occurred efficiently when temperature was again brought to 37°C (Fig. 5 A, third bar); the extent was comparable to the control (first bar) in which LPC had not been added but cells were washed in the same way as if it had. This high level of fusion demonstrates that the action of LPC was reversible and that gp41 was not inactivated when LAS was created. Significantly, blocking fusion (probably at the point of merger of outer leaflets) by the incorporation of LPC into the membrane prevented gp41 from folding into the six-helix bundle: adding T20 (Fig. 5 A, fourth bar) or T21 (fifth bar) after removing the LPC prevented fusion when temperature was raised to 37°C. Mechanistically, the presence of membrane-bound LPC prevented gp41 from transiting into its final and stable six-helix bundle. Thus, we showed that in order for the bundle to form, membrane merger must take place. Therefore, the bundle itself cannot be the cause of membrane merger.

View larger version (33K): [in this window] [in a new window] [Download PPT slide]   Figure 5 The formation of the six-helix bundle requires membrane merger. (A) Adding 285 µM LPC to cells at TAS, followed by removal of the unbound LPC 5 min later, suppressed fusion when temperature was raised to 37°C (LAS, second bar). But removing the membrane-bound LPC allowed fusion to occur at 37°C (third bar). Addition of 40 nM T20 or 440 nM T21 after removing all LPC inhibited fusion when temperature was again increased to 37°C (fourth and fifth bars). Effector cells were bound to target cells that had been grown overnight on untreated glass. (B) Exposure of cells at TAS to 265 µM OA yielded the same extent of fusion (second bar) as the control (first bar). LPC was added to cells at TAS and the unbound fraction was removed (with the cells retaining the membrane-bound LPC); the addition of T20 or T21 (concentrations as in A) followed by removal of the membrane-bound LPC and unbound peptide suppressed fusion (third and fourth bars).

Raising Temperature at TAS Does Not Induce Bundle Formation without Also Causing Fusion.
We devised an alternative approach to test whether the six-helix bundle could form before lipid merger without fusion then occurring. This approach avoided the need to add exogenous agents such as LPC. We reasoned that if the bundle formed before fusion and this structure then induced fusion, one should be able to increase temperature to 37°C for times too short to cause lipid or aqueous dye spread, but sufficiently long to induce the formation of the bundle. (Once formed, the six-helix bundle is extremely stable [Blacklow et al. 1995; Weissenhorn et al. 1996] and hence will not convert back to a prior configuration.) Cells at TAS were quickly brought to 37°C with a T-jump method we devised (see Materials and Methods); with several cell pairs in a field of view, temperature was returned to 4°C as soon as one or two cell pairs were observed to fuse (Fig. 6 A). The fused cells acted as an indicator that temperature had been elevated for a sufficient time to have promoted bundle formation for those cells remaining ("preconditioned cells"). T20 or T21 was added and after maintaining 4°C for 5 min, aqueous dye did not spread when the temperature was again jumped to 37°C (Fig. 6 B, middle and right bars). However, when the peptides had not been added, fusion did occur (Fig. 6 B, left bar). Thus, the bundle had not formed for the preconditioned cells. We tested whether the preconditioned cells were advanced at all beyond TAS to a further stage still before fusion, if in fact such a stage existed. If it did, the kinetics of fusion for the preconditioned cells should be faster than from the point of TAS. The times from the start of the second jump in temperature and fusion of the preconditioned cells were ranked to generate cumulative distributions (Fig. 6 B, inset, triangles). We found that this distribution was close to and no faster than the distribution that occurred when temperatures of cells at TAS were raised and maintained at 37°C (Fig. 6 B, inset, open circles). To verify the accuracy of kinetics obtained by dye spread in our experiments, we used electrical capacitance measurements to monitor the moment that a pore formed between individual cell pairs. Electrical measures provide the greatest temporal resolution and sensitivity for detecting pores. The electrically determined kinetics (Fig. 6 B, inset, filled circles) was statistically identical to those obtained by calcein redistribution (open circles), demonstrating that the rate of Env-induced fusion is reliably monitored by fluorescence microscopy. The kinetic measures thus indicate that any further reconfigurations of gp41 beyond TAS but before bundle formation are less rate limiting than either conversion of gp41 to the bundle and/or lipid rearrangements required for pore formation. If lipid rearrangements were rate limiting, we should have been able to capture preconditioned cells with bundles already formed. Because we could not, we propose that bundle formation is the rate-limiting step. The fact that fusion kinetics was independent of whether temperature had previously been raised to 37°C also suggests that fusion from TAS was stochastic, without "memory" of past temperatures.

View larger version (27K): [in this window] [in a new window] [Download PPT slide]   Figure 6 Fusion evoked from TAS by a T-jump to 37°C. (A) Fluorescence images of fusion between calcein-labeled effector cells and unlabeled target cells (the bright field image is superimposed on the first panel). The times after the T-jump are shown. Arrowhead indicates the first target cell that acquired aqueous dye. Effector and target cells were mixed together and plated on polylysine-coated coverslips. (B) The extents of fusion for preconditioned cells in the absence and presence of peptides. TAS was created and temperature was then decreased to 4°C. Preconditioned cells were generated by increasing the temperature of several cells in a microscopic view to 37°C and once one or two cells fused, quickly lowering the temperature to 4°C. T20 (middle bar) or T21 (right bar) were added or not added (left bar, control) and fusion of the remaining preconditioned cells was induced by again raising temperature to 37°C. Inset: kinetics of fusion when temperature was maintained at 37°C was continuously monitored either by the onset of calcein redistribution () or by measuring the increments in electrical capacitance of cell membranes due to fusion pore opening (•). Fusion kinetics of preconditioned cells measured by calcein redistribution is shown by . (C) Electrical recording of fusion pores formed by Env. A representative pore is shown in the inset. The average pore conductance was determined from eight individual records (•). The right-hand scale shows the approximate pore diameter. Bars indicate the standard error.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
The Formation of the Six-Helix Bundle and Membrane Merger Is Tightly Linked
It is generally agreed that the formation of the six-helix bundle or the structure of the bundle itself must be intimately involved in the fusion process because six-helix bundles are formed for so many viral fusion proteins. However, an opposite view has been argued, that the six-helix bundle forms long after fusion has occurred and is unrelated to the fusion process (Shangguan et al. 1998). But if T20 and T21 prevent HIV Env from folding into a six-helix bundle at the point of bundle formation itself, rather than by preventing a prior upstream conformational change, this latter view could not be correct.

The precise function of the bundle, however, had not been experimentally identified. Most commonly it has been assumed that the purpose of the movement of a fusion protein into a six-helix bundle is to force membranes into close proximity (Weissenhorn et al. 1997; Chan and Kim 1998), in which case subsequent processes such as oligomerization of fusion proteins or structures outside the bundle would promote fusion. The six-helix bundle portions of viral fusion proteins are extremely stable, and therefore after formation should not undergo further conformational changes that would directly induce fusion. The assumption that bundle formation brings membranes into contact is reasonable because the fusion peptide of gp41 probably inserts into the target membrane before fusion (as has been shown for HA; Durrer et al. 1996; Stegmann et al. 1991), and the transmembrane (TM) domain that is located within the viral membrane would, logically, pull the two membranes together as the hairpin bend forms. Investigators generated fragments of ectodomains of fusion proteins that contained the preassembled six-helix bundle as well as other portions of the protein in order to determine how the bundle and regions outside the bundle could interact with membranes to promote hemifusion and/or fusion from a state of close membrane apposition (LeDuc et al. 2000). Alternatively, it has been suggested that the formation of the six-helix bundle does not simply bring membranes into close apposition, but that conformational changes of fusion proteins into the bundle directly couple to membrane fusion (Baker et al. 1999): the fusion peptides and TM domains of some fusion proteins form a continuous structure with their adjacent HRs (Baker et al. 1999), which immediately suggests that these two domains should come into close proximity as the six-helix bundle forms. However, for other fusion proteins such continuous structures do not exist (Chen et al. 1999).

We have shown that the addition of LPC to outer leaflets of membranes prevents gp41 from folding into a six-helix bundle: even though all other fusion conditions, including temperature, were optimal and should have allowed bundles to form, they did not form. LPC has prevented bundle formation, and has done so through some effect on the lipid bilayer portion of the membrane. Since the incorporation of LPC into membranes prevents hemifusion, we can logically conclude that preventing hemifusion is that effect. If we assume that LPC has no further effect than to prevent hemifusion, we can further conclude that upon its removal, the bundle could not have formed before hemifusion and then induce hemifusion, or the bundle would have been able to form in the presence of LPC. We cannot rule out the remote possibility that LPC prevents bundle formation through some effect other than hemifusion, some unknown effect that blocks bundle formation. But there is no evidence that LPC in membranes could inhibit the kind of large scale conformational changes that occur in the ectodomain by any means other than hemifusion and/or fusion. In fact, to the limit of the time resolution of the kinetic experiments, the finding that gp41 of preconditioned cells had not yet folded into a six-helix bundle provides independent support for the hypothesis that without hemifusion (or fusion) the bundle does not form. If bundle formation is essential for membrane merger, and membrane merger is required for bundle formation, then membrane merger occurs as some of the fusion proteins are assuming the six-helix bundle.

Mechanistically, fusion could take place as follows. Fusion peptides insert into the target membrane, and as the fusion proteins bend into six-helix bundles, the fusion peptides and TM domains pull the two membranes locally toward each other (Weissenhorn et al. 1997; Chan and Kim 1998). For every viral fusion protein in which the six-helix bundle has been observed, each of the COOH-terminal helices has been shown to pack on the outside of and antiparallel to the NH₂-terminal coiled coil (Skehel and Wiley 1998). For this crystallographically identified bundle to actually form, the fusion peptides (arrows of Fig. 7) and TM domains should come close to each other, and because the bundle exhibits threefold symmetry, the two membrane-inserted regions may even intermingle. Membrane continuity would be a necessary concomitant for these two domains, inserted in different membranes, to come into contact. Hemifusion could occur before folding of gp41 into the bundle (this is consistent with our LPC results), and the formation of the bundle could disrupt a small hemifusion diaphragm and thereby create the pore. This could also be the case for many other viral fusion proteins. In fact, for HA of influenza virus, a large body of evidence indicates that fusion is initiated through hemifusion (Kemble et al. 1994; Melikyan et al. 1997; Chernomordik et al. 1998). It has been advocated that the TM domain (Kemble et al. 1994; Melikyan et al. 1999; Markosyan et al. 2000) and the fusion peptide (Qiao et al. 1999) effect fusion by breaking the hemifusion diaphragm.

View larger version (31K): [in this window] [in a new window] [Download PPT slide]   Figure 7 A proposed sequence of events for Env-mediated membrane fusion. The relative positions of HR1 and HR2 in the bound state are not known and only HR1 is depicted. (Neither CD4 nor the coreceptors are shown.) When gp41 is activated, the grooves of the central coiled coil (light gray bars with fusion peptide indicated by arrows) and the COOH-terminal helices (dark gray bars attached to the TM domain and cytoplasmic tail) have become exposed. The gp120 on the left is made transparent, for clarity. When gp41 further reconfigures into a six-helix bundle, the fusion peptide and TM domain (in different membranes) are forced toward each other and induce pore formation (probably by rupturing the hemifusion diaphragm, not shown).

Whereas ectodomains free in solution readily form six-helix bundles, when the ectodomain is membrane anchored the transition would be physically far more difficult. Steric constraints should make it rather difficult for individual HR2 segments within a gp41 trimer to move away from each other and into close contact with their respective HR1 segments, since the HR2 segments are continuous with the TM domains and there is only a short stretch of amino acids between them. Thus, although considerable free energy is released by six-helix bundle formation, the process may not be spontaneous and a large activation barrier may have to be surmounted. A large activation barrier would account for the steep temperature dependence of fusion from TAS.

The Energy Barriers Upstream of TAS Are Smaller Than Those between Tas and Fusion
The longer time before the start of fusion (the lag) from 4°-TAS than from TAS (upon raising temperature to 37°C) shows that the steps contributing to the delay are temperature dependent. A step that intervenes between TAS and fusion was more highly temperature dependent than the steps preceding TAS: fusion does not occur at 23°C but does at 37°C. In terms of energetics this could mean that the barriers between cell–cell contact and TAS are lower than between TAS and fusion. This difference in barriers could be the reason we were able to capture TAS as a stable intermediate state just before fusion. If the energy barriers before TAS were not large, many steps would occur before TAS because delays until fusion were long when cells were maintained at 37°C (Fig. 3 A). Multiple copies of Env (and possibly CD4 and/or CXCR4) may have moved into and associated with each other at a site where the pore could be created (Frey et al. 1995; Weissenhorn et al. 1997; Munoz-Barroso et al. 1998). It is unlikely that the association of Env into a complex is so highly temperature dependent that it does not occur at 23°C: the preconditioned cells fused no faster than when temperature was originally raised and maintained (Fig. 6 B).

Possible Utility of Creating TAS
Although many fusion proteins reconfigure into six-helix bundle structures, the fusion pores created by these different proteins exhibit distinct characteristics. The fusion pores formed by HIV Env had not been previously measured electrically. By first creating TAS and then patch clamping cells, we developed a means to routinely electrically measure HIV Env–induced fusion pores. These pores have large sizes within milliseconds of formation, grow rapidly, and do not flicker. Each of these features contrasts with pores induced by influenza virus HA, the most extensively characterized fusion pore. The fusion pores induced by Moloney murine leukemia virus Env protein, the only other retroviral fusion pore electrically measured (Melikyan et al. 2000), also does not flicker and grows rapidly, but the initial HIV Env pore is larger than that of Moloney.

As a practical matter, the remarkable stability of exposure of a highly conserved region of gp41 and the convenience of releasing TAS on to fusion may be potentially useful for testing drugs that bind to this region (Eckert et al. 1999; Ferrer et al. 1999) and for the development of a broadly effective HIV vaccine. CD4 and coreceptor-triggered HIV Env can elicit antibodies that neutralize infectivity of diverse HIV isolates (LaCasse et al. 1999). For the immunogen to have elicited broadly effective antibodies, conserved regions of HIV Env must have been exposed (LaCasse et al. 1999); these may be the same regions that are readily and reliably exposed for long times by creating TAS.

In conclusion, we have shown that the six-helix bundle does not form in the absence of membrane merger and verified that fusion does not occur if the bundle cannot form. Thus, it is not the six-helix bundle as a stable protein configuration that causes fusion, but rather the free energy released when gp41 undergoes this conversion that is directly and immediately used for pore formation. We propose that all viral fusion proteins that form six-helix bundles will likely achieve fusion through the same or similar mechanisms as HIV Env. There may even be some parallels in eukaryotic fusion: intracellular membrane fusion is thought to be mediated by SNAREs (Südhof 1995; Hay and Scheller 1997; Weber et al. 1998), and SNAREs form a heterotrimeric, parallel four-helix bundle (Poirier et al. 1998; Sutton et al. 1998). The energy released during this bundle assembly may contribute to intracellular fusion.

	Acknowledgments

 
We thank the AIDS Research and Reference Reagent Program, Division of AIDS, National Institute of Allergy and Infectious Diseases, National Institutes of Health, for providing materials, and Dr. Z. Jonak of SmithKline Beecham for supplying the TF228.1.16 cell line. We are grateful to Drs. L.V. Chernomordik, R.A. Lamb, and J. Rucker for critical readings of the manuscript.

Supported by National Institutes of Health grants GM27367 and GM54787.

Submitted: 29 March 2000

Revised: 23 August 2000

Accepted: 29 August 2000

The online version of this article contains supplemental material.

Abbreviations used in this paper: CMAC, 7-amino-4-chloromethylcoumarin; CXCR4, chemokine receptor; DiI, 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate; HA, hemagglutinin; HR, heptad repeat; IR, infrared; LAS, lipid-arrested stage; LPC, lysophosphatidylcholine; OA, oleic acid; SNARE, soluble N-ethylmaleimide–sensitive factor attachment protein receptor; TAS, temperature-arrested stage; TM, transmembrane.

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