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Intrasequence GFP in Class I MHC Molecules, a Rigid Probe for Fluorescence Anisotropy Measurements of the Membrane Environment

Jonathan V. Rocheleau ^*, Michael Edidin  and David W. Piston ^*

^* Department of Molecular Physiology and Biophysics, Vanderbilt University, Nashville, Tennessee; and Department of Biology, The Johns Hopkins University, Baltimore, Maryland

Correspondence: Address reprint requests to David W. Piston, 702 Light Hall, Dept. of Molecular Physiology and Biophysics, Vanderbilt University, Nashville, TN 37232. Tel.: 615-322-7030; E-mail: Dave.Piston{at}vanderbilt.edu.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

 
Fluorescence anisotropy measurements can elucidate the microenvironment of a membrane protein in terms of its rotational diffusion, interactions, and proximity to other proteins. However, use of this approach requires a fluorescent probe that is rigidly attached to the protein of interest. Here we describe the use of one such probe, a green fluorescent protein (GFP) expressed and rigidly held within the amino acid sequence of a major histocompatibility complex (MHC) class I molecule, H2L^d. We contrast the anisotropy of this GFP-tagged MHC molecule, H2L^dGFPout, with that of an H2L^d that was GFP-tagged at its C-terminus, H2L^dGFPin. Both molecules fold properly, reach the cell surface, and are recognized by specific antibodies and T-cell receptors. We found that polarized fluorescence images of H2L^dGFPout in plasma membrane blebs show intensity variations that depend on the relative orientation of the polarizers and the membrane normal, thus demonstrating that the GFP is oriented with respect to the membrane. These variations were not seen for H2L^dGFPin. Before transport to the membrane surface, MHC class I associates with the transporter associated with antigen processing complex in the endoplasmic reticulum. The intensity-dependent steady-state anisotropy in the ER of H2L^dGFPout was consistent with FRET homotransfer, which indicates that a significant fraction of these molecules were clustered. After MCMV-peptide loading, which supplies antigenic peptide to the MHC class I releasing it from the antigen processing complex, the anisotropy of H2L^dGFPout was independent of intensity, suggesting that the MHC proteins were no longer clustered. These results demonstrate the feasibility and usefulness of a GFP moiety rigidly attached to the protein of interest as a probe for molecular motion and proximity in cell membranes.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

 
Fluorescence polarization methods can give information on the formation and size of molecular clusters in living cells. Fluorescence resonance energy transfer (FRET) homotransfer resulting from fluorophore aggregation can be detected through a decrease in fluorescence steady-state anisotropy (Blackman et al., 1998). In addition, polarized fluorescence recovery after photobleaching can resolve molecular rotation (Velez and Axelrod, 1988; Yuan and Axelrod, 1995; Timbs and Thompson, 1990). The rotational diffusion of a membrane protein is proportional to the effective radius squared (Saffman and Delbrük, 1975), which means that even a small change in the effective radius, such as protein dimerization, strongly affects a protein's rotational diffusion. Fluorescence polarization techniques can therefore be used to elucidate the aggregate formation and size of aggregates of appropriate fluorescently tagged molecules, even in cell endomembranes, such as the endoplasmic reticulum (ER).

In this work, we have used fluorescence polarization techniques to analyze the synthesis and assembly of major histocompatibility complex (MHC) class I molecules in the ER (Pamer and Cresswell, 1998). During their assembly MHC class I molecules are retained in the ER through association with chaperones and a complex of proteins including transporter associated with antigen processing (TAP), calnexin, calreticulin, tapasin, and ERp57 (Cresswell et al., 1999). This complex supplies nascent MHC class I with antigenic peptides that are generated in the cytosol by proteosomes. The supply of these peptides results in MHC class I dissociation from the TAP complex, a step that can be detected by measuring lateral diffusion of green-fluorescent-protein-tagged (GFP) MHC I molecules (Marguet et al., 1999), and exit from the ER to the plasma membrane (Suh et al., 1994). Until recently, dissociation from the TAP complex was thought to be the final event for exit of MHC class I from the ER (Suh et al., 1994; Lewis et al., 1996; Neisig et al., 1998). However, recent experiments show that peptide-loaded MHC class I is retained in the ER long enough to exchange for other peptides with more optimal MHC binding (Lewis and Elliott, 1998). Peptide-loaded MHC I molecules then appear to exit the ER by a receptor/carrier-mediated mechanism involving clustering of class I molecules detectable by FRET between cyan- and yellow-fluorescent protein (CFP and YFP)-tagged class I molecules (Marguet et al., 1999; Spiliotis et al., 2000; Pentcheva and Edidin, 2001; Pentcheva et al., 2002).

GFP-tagged MHC class I molecules offer the possibility of elucidating the extent and timing of molecular aggregation. Fluorescence anisotropy can be used to detect clustering by homotransfer FRET (Clayton et al., 2002; Gautier et al., 2001), and to evaluate the size of the clusters in terms of their rotational diffusion (Velez and Axelrod, 1988). To this end, we have compared the fluorescence anisotropies of two different GFP-tagged MHC class I molecules, H2L^dGFPin and H2L^dGFPout, expressed in L-cells. Both of these are functional proteins, recognized by specific antibodies and by the appropriate T-cell receptor (Marguet et al., 1999). The H2L^dGFPin has a GFP attached to its cytoplasmic tail at the C-terminus and is more likely to report on segmental rather than whole protein rotational motion (Hink et al., 2000). The second form of the H2L^d protein, H2L^dGFPout, has its GFP within the amino acid sequence of the H2L^d protein. As shown here, this construct holds the GFP rigid relative to the H2L^d protein and thus makes it amenable to polarized fluorescence measurements. In comparison to H2L^dGFPin, H2L^dGFPout binds the MHC class I light chain, b2m, weakly, and associates poorly with TAP, but it is loaded with peptide and transported out of the ER to the cell surface where it is recognized by specific monoclonal antibodies and by a specific T-cell receptor. In this study, we compare the ways in which GFP reports on MHC class I orientation and environment when it is placed intrasequence or on the C-terminal of the molecule.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

 
Cells lines and culture
Two separate EGFP-expressing mouse fibroblast cell lines generated previously from L-M(tk^-) (H2^k) (ATCC CCL 1.3), (Marguet et al., 1999), were used in these studies. These cell lines express two different GFP-tagged forms of the mouse MHC class I allele, H2L^d. One form, H2L^dGFPin, was labeled with GFP at the C-terminal cytoplasmic tail of the native protein. The second form, H2L^dGFPout, was labeled with GFP placed between the 3- and transmembrane-domains of the native protein (Marguet et al., 1999). In this construct, the GFP is flanked by N- and C-terminal linkers containing six residues (PGSIAT and LGMDEL for N- and C-terminus, respectively). These cells were maintained in RPMI medium (Gibco, Grand Island, NY) supplemented with 2 mM L-glutamine, 10 mM HEPES, and 10% heat-inactivated fetal bovine serum (Gibco), and 300 µg/ml G418. Cos7 cells were maintained in DMEM with 10% heat-inactivated fetal bovine serum. Both cell lines were routinely plated on 35-mm glass bottom dishes (MatTek, Ashland, MA) for polarized confocal laser scanning microscopy. H2L^dGFPin and H2L^dGFPout cells were incubated overnight at 28°C before observation, which increased H2L^dGFPout expression. Cells were placed in imaging buffer containing 125 mM NaCl, 5.7 mM KCl, 2.5 mM CaCl₂, 1.2 mM MgCl₂, and 10 mM HEPES (pH 7.4) before imaging. MCMV (YPHFMPTNL), a peptide from MCMV pp89 (Reddehase et al., 1989), was made by F-MOC chemical synthesis and then purified by preparative HPLC. MCMV-loading was done overnight by placing the cells in media containing 100 µM MCMV (Marguet et al., 1999). Cells were also routinely treated with 10 µM lactacystin (Kamiya Biomedical, Seattle, WA) in DMEM for 30 min and washed with warm imaging media before experiments (Marguet et al., 1999).

Transient GFP-construct transfections
Cos7 cells were transiently transfected with pEGFP-C1 (BD Biosciences Clontech, Mountain View, CA), pActin-GFP (BD Biosciences Clontech), and epidermal growth factor receptor (pEGFR)-GFP using an ECM 830 BTX square wave electroporator (Genetronics, Sorrento, CA). The cells were transfected with 5 µg of plasmid using ten 50-µs square wave pulses of 300 V with 500-ms intervals. Cells were observed 24–48 h after transfection.

Fluorescence spectroscopy
Fluorescence of GFP solutions was collected on a PTI T-format fluorescence spectrometer running FeliX version 1.42a (Photon Technologies International, Lawrenceville, NJ).

Polarized confocal laser scanning microscopy
Polarized fluorescence images were collected using a Zeiss LSM 410 confocal microscope with a 40 x 1.3 numerical aperture (NA) Plan-NEOFLUAR objective lens (Zeiss, Thornwood, NY). Samples were illuminated by overfilling the back aperture of the objective lens with the 488-nm laser and emission was collected through a 515- to 525-nm bandpass filter. Excitation and emission light passed through rotatable film polarizers placed in the beam path in slots provided by the manufacturer. Images were collected at 0.1-µm/pixel resolution unless otherwise stated. The apparatus g-factor was determined by imaging deep well solutions of fluorescein and GFP. A half-wave plate was used to change the excitation polarization from horizontal to vertical, and the g-factor for the microscope (0.672) was calculated to resolve the equation vv/g x vh = g x hh/hv, determined from the end-on detection geometry (Blackman et al., 1996).

Large NA corrections for confocal anisotropy measurements
Fluorescence anisotropy measurements involve photoselectively exciting the sample with polarized light, and then collecting the emitted fluorescence intensity through polarizers oriented parallel (I_||) and perpendicular (I) to the excitation polarization. Fluorescence anisotropy, r, is conventionally defined as:

(1)

When observations are made through a high NA objective lens, detection in the parallel and perpendicular direction becomes mixed due to the out-of-plane projections of the emission dipoles (Axelrod, 1979, 1989). In the geometric convention where the z-axis corresponds to the optical axis, leaving the x- and y-axes corresponding to the directions with emission polarizer placed parallel and perpendicular to the excitation polarizer, respectively, the observed intensities are given by:

(2)

Here, I_x,y,z are the intensities observed through a polarizer oriented along x-, y-, and z-axes, detected through a small aperture, and K_a,b,c are weighting factors that depend on the numerical aperture (exact forms found in Axelrod, 1979). For the limit of 0 NA, K_c = 1, and K_a = K_b = 0. If the fluorophore is randomly oriented, then I_z = I_y, which allows solving for I_x and I_y and calculation of the aperture-corrected, steady-state anisotropy (Axelrod, 1989).

Relative membrane orientation measured using steady-state anisotropy
A model addressing the steady-state fluorescence anisotropy signal of a chromophore as a function of orientation, in a confocal microscope field has been previously described (Blackman et al., 1996). This model describes the determination of the relative orientation of a membrane-associated chromophore from steady-state fluorescence polarization images of spherical membrane samples (red blood cell ghosts). Briefly, this technique utilizes fluorescent polarization images from the cross sections of spherical membrane geometry samples (Fig. 1 A). In these images, the confocal image plane produces a circular sample of the membrane, with the amount of membrane sampled related to the angle between the plane and the full-width at half-maximum of the z-resolution (). Images are collected with the emission polarizer perpendicular and parallel to the excitation polarizer. A probe that is oriented relative to the circular membrane demonstrates I_|| and I intensities that vary with the angle of observation around the circumference of the sampled membrane. These intensity variations are a function of the angle of observation around the membrane, ß, the relative angle of the absorption and emission dipoles to the membrane normal, _a and _e (Fig. 1 B), and three correlation functions (C₀, C₁, and C₂). These correlation functions are constrained:

(3)

The uniaxial rotational diffusion model allows explicit description of these three correlation functions (Blackman et al., 1996). Intensity around the circular membrane varies only if the probe is oriented relative to the membrane.

View larger version (11K): [in this window] [in a new window]   FIGURE 1  Definition of angles used to describe the geometries obtained from a confocal image of a cell bleb. (A) Image plane of a spherical membrane. Excitation polarizer was kept horizontal while images were collected with emission polarizer parallel and perpendicular to this. Intensity is extracted from these images as a function of the angle around the membrane (ß). (B) Parameters used in geometric model. N is the membrane normal axis. The absorption and emission dipole vectors, a and e, are described by the angles between N and the vector (a and e) as well as the rotation of e around N().

Whole cell photobleach measurements
A series of 90 images was collected from the same field of view, with the emission polarizer alternating between the parallel and perpendicular polarization detection for each successive image. The images were each collected in 2.16 s at 0.2-µm/pixel resolution and included 3–10 cells. As the series progressed, the fluorescence in all cells was photobleached (i.e., the imaging laser intensity was sufficient for photobleaching over the timecourse of 90 images). Each successive parallel-perpendicular image pair provided an anisotropy measurement. The intensity for anisotropy calculation was extracted from the ER regions of individual cells using Metamorph Software 4.6 (Universal Imaging, Downington, PA). These bleaching sequences were carried out from 5 to 10 times and involved from 15 to 30 cells for each treatment.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

 
Steady-state anisotropy of GFP
Steady-state fluorescence anisotropy measurements were obtained for various GFP samples (Table 1). Included in this table are spectrometer and confocal microscope measurements of purified GFP in solution as well as confocal microscope measurements of various GFP constructs transiently expressed in cultured fibroblasts. The measurements of purified GFP in solution were done to verify the correction factors used for the high NA lens of the confocal measurement. The anisotropy measured using a fluorescence spectrometer was only slightly larger than that measured on the microscope stage, and both compared well with previous GFP steady-state measurements (Swaminathan et al., 1997; Clayton et al., 2002). Therefore, the correction factors used were adequate to compensate for the high NA of the objective lens.

Orientation-dependent fluorescence
Two cell lines expressing MHC class I constructs were used with GFP either attached at the C-terminus, H2L^dGFPin; or internally between the 3- and transmembrane-domains of the native protein, H2L^dGFPout (Marguet et al., 1999). These cells were induced to form plasma membrane blebs using 1 mM H₂O₂ in imaging buffer (Tank et al., 1982). These blebs were stable and formed a spherical membrane geometry (5.9 ± 0.3 µm radius) lacking internal fluorescence. The chromophore orientation relative to the membrane normal was examined to determine whether intrasequence expression of the GFP tag rigidly attached the probe to the MHC class I protein (Materials and Methods). It was expected that the GFP moiety of H2L^dGFPin would show segmental motion, so its anisotropy served as a limited case comparison to the anisotropy of H2L^dGFPout. Shown in Fig. 2 are representative polarized fluorescence confocal images of H2L^dGFPin (Fig. 2, A, C, and E) and of H2L^dGFPout (Fig. 2, B, D, and F). In these images the excitation polarization was kept horizontal (h) and the emission polarizer was set at either horizontal (hh or ||; Fig. 2, A and B) or vertical (hv or ; Fig. 2, C and D). The intensity around the H2L^dGFPin blebs appeared to be uniform in both the hh- and hv-images (Fig. 2, A and C). In contrast, the intensity in the hh-image of the H2L^dGFPout (Fig. 2 B) varied with the angle (ß) around the membrane bleb. This variation in intensity can be observed in the pseudocolor overlap of the polarized images, shown with emission horizontal (hh, green) and vertical (hv, red) (Fig. 2, E and F). In these pseudocolor images, the H2L^dGFPin color varies little around the cell bleb (Fig. 2 E), but in contrast the H2L^dGFPout color shows a capping of red (minimum) and green (maximum) fluorescence (Fig. 2 F). Intensity around these membranes was measured at 10° intervals in >100 blebs for each construct (Fig. 3). The H2L^dGFPin images demonstrated uniform intensity around the blebs, which is consistent with a random orientation of the GFP relative to the membrane (Fig. 3 A). In contrast, the intensity varied significantly around the blebs of H2L^dGFPout cells (Fig. 3 B). This shows that the GFP of the H2L^dGFPout molecule is oriented relative to the membrane.

View larger version (42K): [in this window] [in a new window]   FIGURE 2  Fluorescence polarization images of H2LdGFPin and H2LdGFPout cell blebs. The excitation polarizer was kept horizontal for the collection of these images. These images were collected on H2LdGFPin (A, C, and E) and H2LdGFPout (B, D, and F) cells that were induced to bleb using 1 mM H2O2. The emission polarizer was placed parallel (hh) for the collection of A and B. The emission polarizer was placed perpendicular (hv) for the collection of C and D. These images are also shown superimposed upon one another with pseudocolored green (hh) and red (hv). The bar shown in F is 5 µm.

View larger version (20K): [in this window] [in a new window]   FIGURE 3  Fluorescence polarization intensities obtained from the periphery of cell blebs. Intensity was extracted at 10° increments from >100 membrane blebs for both H2LdGFPin (A) and H2LdGFPout (B). The H2LdGFPout intensity varied substantially in both the Ihh and Ihv images and this allowed least-squares analysis fitting using the model described (Materials and Methods). Error bars indicate the standard error of the mean for each angle (ß) measured.

Peptide loading of H2L^dGFP in cells
Since the GFP moiety of H2L^dGFPout had a rigid orientation to the membrane, the anisotropy of this reporter was likely to reflect the rotational mobility of the whole molecule. To test whether the GFP was rigid to the protein, we used the peptide MCMV (YPHFMPTNL) (Reddehase et al., 1989), whose affinity for H2L^d is 10⁹ M^-1. When exogenously given to cells, MCMV-peptide binds to MHC class I molecules in the ER. After binding, the peptide-loaded MHC class I molecules then traffic to the membrane surface (Day et al., 1997; Marguet et al., 1999). If the GFP was rigidly attached to its construct protein, any changes in environment as it traffics to the plasma membrane were likely to be reflected in anisotropy changes. Such anisotropy changes thus reflect the environment of the whole molecule. Fluorescence intensity measurements were carried out using the confocal microscope, which permits specific intensity measurements from the ER regions of individual cells. For comparison, these studies were done in parallel with H2L^dGFPin. Shown in Fig. 4 are the scatter plots of the steady-state anisotropy of H2L^dGFP for individual cells plotted against the average total intensity (I_,||) of ER fluorescence. The average steady-state anisotropy is also indicated at the bottom right of each panel (summarized in Table 2). MCMV treatment caused no detectable change in the anisotropy of the H2L^dGFPin cells (Fig. 4, A and B). In contrast, the steady-state anisotropy of the MCMV-treated H2L^dGFPout cells was significantly larger than untreated (Fig. 4, C and D). This change is consistent with a rigid attachment between GFP and H2L^d. None of the four anisotropies showed a significant dependence on the total average intensity (I_,||) suggesting that there was no significant FRET between randomly distributed molecules. However, the steady-state anisotropy of H2L^dGFPout, without added peptide, was significantly lower than the anisotropy of H2L^dGFPin. Therefore, although our data indicate that concentration-dependent (nonspecific) homotransfer did not occur, the lower-than-expected steady-state anisotropy strongly suggested homotransfer FRET between clustered molecules. This FRET is almost completely abolished after feeding peptide to the cells.

View larger version (28K): [in this window] [in a new window]   FIGURE 4  Steady-state fluorescence anisotropy obtained from the ER of H2LdGFPin (A and B) and H2LdGFPout (C and D). The anisotropy was calculated using the correction factors described (Materials and Methods) from intensities extracted from confocal images. The intensities were extracted from individual cells from regions thought to be the ER. MCMV treatment was done at a concentration of 100 µg/ml in cell media overnight (B and D). In the bottom right corner is the average steady-state anisotropy measured (mean ± SE) from H2LdGFPin (N = 262), H2LdGFPin + MCMV (N = 318), H2LdGFPout (N = 196), and H2LdGFPout + MCMV (N = 212).

View larger version (25K): [in this window] [in a new window]   FIGURE 5  Controlled bleach experiments of H2LdGFPin and H2LdGFPout cells. Images were collected sequentially as described (Materials and Methods), which resulted in gradual bleaching of the GFP fluorescence. Bleach measurements were done on H2LdGFPin (A, N = 5), H2LdGFPin + MCMV (B, N = 5), H2LdGFPout (C, N = 5), and H2LdGFPout + MCMV (D, N = 10). N represents the number of fields of view used in each bleach curve and each field of view contained from 3–6 cells. These curves were fit linearly and the y-intercept is shown in the bottom left of each graph (± 95% confidence interval). This value is referred to as the null homotransfer anisotropy.

View larger version (18K): [in this window] [in a new window]   FIGURE 6  Controlled bleach experiment with lactacystin-treated H2LdGFPout cells. Images were collected sequentially as described (Materials and Methods), which resulted in gradual bleaching of the GFP fluorescence. Bleach measurements were done on H2LdGFPout (, N = 5) and H2LdGFPout + lactacystin treatment (•, N = 10).

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

The polarized fluorescence intensity around plasma membrane blebs was uniform for H2L^dGFPin but varied for H2L^dGFPout (Fig. 2). This result indicates that the relative membrane orientation of the GFP reporter is random for H2L^dGFPin and rigid for H2L^dGFPout. Fitting the H2L^dGFPout intensity variations provided nearly co-linear absorption (49° ± 0.7) and emission (52° ± 1.5) dipoles. The initial anisotropy (r₀) of any fluorophore decreases from 0.4 as the angle between absorption and emission dipoles increases. Therefore, the closeness of the fitted angles agrees with previous studies, which have shown the r₀ of GFP to be nearly 0.4 (Volkmer et al., 2000). These data are all consistent with the GFP moiety of H2L^dGFPin being randomly oriented relative to the membrane, and the GFP of H2L^dGFPout adopting a more constrained orientation. This rigidity is likely due to the constraints placed on both the N- and C-terminus of the GFP. It is not clear if this rigidity is due to short linker sequences (six residue linkers on both ends) or direct interaction between GFP and the membrane. However, it is likely that the rigidity of this attachment would decrease with increased linker length.

We observed no change in the steady-state anisotropy of H2L^dGFPin after MCMV peptide loading (Fig. 4). This is consistent with the C-terminal GFP of H2L^dGFPin not fully reporting the environment of the H2L^d molecule. Previous FRET measurements suggest that peptide-loaded C-terminally tagged MHC class I molecules are clustered as they are staged for ER exit (Pentcheva and Edidin, 2001). This difference may arise because different MHC class I molecules were used in the two sets of experiments, and were expressed in different cells. The earlier work was done with human MHC class I molecules, HLA-A2, expressed in HeLa cells, whereas the present study is of mouse MHC class I molecules expressed in mouse L-cells. This difference may also arise due to differences between the two experimental methods and their ability to detect FRET (anisotropy changes versus acceptor photobleaching). In particular, the CFP-YFP heterotransfer used in the previous studies has a slightly larger Forster distance (4.92 ± 0.10 nm) than the GFP-GFP homotransfer used in these studies (4.65 ± 0.09 nm) (Patterson et al., 2000). Such a difference is likely to have reduced our chances of observing any H2L^dGFPin homotransfer FRET.

The H2L^dGFPout steady-state anisotropy was more homotransfer-dependent than H2L^dGFPin and increased in response to MCMV-peptide loading (Fig. 5). The change in H2L^dGFPout anisotropy is consistent with a rigid attachment between GFP and H2L^d. The differences between H2L^dGFPout and H2L^dGFPin indicate that these two probes are either behaving dissimilarly in the cell (reporting on different regions) or that the placement of the GFP moiety on MHC class I modifies the donor-acceptor distance. Resonance energy transfer efficiency is strongly affected by changes in the donor-acceptor distance on the order of a typical globular protein (20–40 Å). Hence, it is important to note that placement of the GFP intrasequence of a protein can offer alternatives to end-terminal labeling. It is also intriguing to speculate that the Forster distance (R₀) of H2L^dGFPout increased due to its rigid attachment, arising because of a better relative orientation factor (²) between donor and acceptor dipoles. However, this is unlikely since only the most rigid probes demonstrate a ² that deviates from two-thirds (van der Meer, 1999). Therefore, the changes in H2L^dGFPout anisotropy likely reflect the fact that the GFP held rigidly within the H2L^d molecule reports the changes in its neighbors and environment as it matures through the ER.

The observed H2L^dGFPout homotransfer indicates that this protein is aggregated in the ER, and the decrease in its homotransfer after peptide loading suggests a dispersal of these aggregates. Lactacystin treatment did not alter the observed homotransfer (Fig. 6), which is consistent with this clustering occurring at the TAP complex. This is in contrast to previous FRAP and FRET measurements that indicate MHC class I molecules cluster as they are staged for ER exit (Pentcheva and Edidin, 2001). In comparison to H2L^dGFPin, H2L^dGFPout binds to the MHC class I light chain, b2m, weakly, and associates poorly with TAP. However, these differences are unlikely to account for the observed FRET behavior, inasmuch as an HLA-A2 mutant that also does not associate with TAP does cluster after peptide loading (Pentcheva and Edidin, 2001). It is also possible that the lack of detectable FRET after peptide loading is due to the lowered technique sensitivity and the decreased GFP-GFP Forster distance compared to CFP-YFP (as suggested previously for the lack of H2L^dGFPin FRET detection). However, this would dictate that the TAP associated FRET observed with H2L^dGFPout occurs due to optimal geometric positioning of the GFP. This would only fit our data if the optimal positioning of H2L^dGFPout at the TAP complex resulted in C-terminal separation that does not allow the detection of H2L^dGFPin homotransfer FRET. Clearly, our results open the way for further experiments—for example, polarization FRAP that can further define the environment of nascent MHC class I molecules. Such experiments will be needed to resolve the differences between the results reported here and earlier work using hetero-FRET to detect clusters of class I molecules.

	ACKNOWLEDGEMENTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

 
The authors thank S.M. Blackman for helpful discussion relating to data analysis. The pEGFR-EGFP was a kind gift from J. Staros.

This work was supported by National Institutes of Health grants DK53434 and CA86283 to D.W.P., and AI-14584 to M.E.; and a National Science Foundation grant DBI-9871063 to D.W.P. A National Institutes of Health Individual National Research Service Award, DK59737, also supported J.V.R. Steady-state anisotropy imaging was performed, in part, through the use of the Vanderbilt University Medical Center Cell Imaging Core Resource, which is supported by National Institutes of Health grants CA68485 and DK20593.

Submitted on October 10, 2002; accepted for publication December 23, 2002.

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