§
* Cell Biology and Metabolism Branch, National Institute of Child Health and Human Development, National Institutes of
Health, Bethesda, Maryland 20892; National Institute of Neurological Disorders and Stroke, NIH, Bethesda, Maryland 20892; § Department of Physiology, University of Connecticut Health Center, Farmington, Connecticut 06032; and
Department of
Physics, Cornell University, Ithaca, New York 14853
The Golgi complex is a dynamic organelle engaged in both secretory and retrograde membrane traffic. Here, we use green fluorescent protein-Golgi protein chimeras to study Golgi morphology in vivo. In untreated cells, membrane tubules were a ubiquitous, prominent feature of the Golgi complex, serving both to interconnect adjacent Golgi elements and to carry membrane outward along microtubules after detaching from stable Golgi structures. Brefeldin A treatment, which reversibly disassembles the Golgi complex, accentuated tubule formation without tubule detachment. A tubule network extending throughout the cytoplasm was quickly generated and persisted for 5-10 min until rapidly emptying Golgi contents into the ER within 15-30 s. Both lipid and protein emptied from the Golgi at similar rapid rates, leaving no Golgi structure behind, indicating that Golgi membranes do not simply mix but are absorbed into the ER in BFA-treated cells. The directionality of redistribution implied Golgi membranes are at a higher free energy state than ER membranes. Analysis of its kinetics suggested a mechanism that is analogous to wetting or adsorptive phenomena in which a tension-driven membrane flow supplements diffusive transfer of Golgi membrane into the ER. Such nonselective, flow-assisted transport of Golgi membranes into ER suggests that mechanisms that regulate retrograde tubule formation and detachment from the Golgi complex are integral to the existence and maintenance of this organelle.
THE Golgi complex is responsible for net transport of
protein and lipid from the ER to more distal compartments (including lysosomes and the plasma
membrane) and recycling of membrane components back
to the ER. It also is involved in important biochemical
processes (i.e. glycosylation of proteins and biosynthesis of
lipids) that enable the cell to tailor its biosynthetic and
secretory products for specific needs. The characteristic
structural elements of the Golgi complex responsible for
these properties include polarized stacks of flattened cisternae enriched in glycoprotein and glycolipid processing
enzymes, and vesicles and tubules associated with the rims
of stacks (Rambourg and Clermont, 1990 The standard view of Golgi traffic is that it is mediated
primarily by vesicles that pinch off from one cisterna and
then target to and fuse with a different cisterna (Rothman
and Wieland, 1996 Tubules could act as discrete carriers in Golgi traffic,
resembling elongated vesicles that migrate within the cytoplasm or translocate along microtubules to their target membranes, unidirectionally and without causing mixing. Alternatively, tubules could establish connections/linkages
between the same or different compartments. In the latter
case, mechanisms would be needed to explain how maintenance of the chemical distinctions between compartments and directed transport of protein and lipid is achieved.
Membrane traffic has been shown to be mediated by tubules extending between organelles in cells treated with
the drug brefeldin A (BFA).1 BFA blocks membrane export out of the ER in vivo (Fujiwara et al., 1988 In this study we exploit previously developed and characterized green fluorescent protein (GFP)-Golgi chimeric
proteins (Cole et al., 1996a Flows are common in fluid systems having free energy
differences either across or along their surfaces (Finkelstein, 1987 Materials
Brefeldin A was purchased from Epicenter Technologies (Madison, WI)
and was used at concentrations of 2-5 µg/ml. Nocodazole was purchased
from Sigma Chemical Co. (St. Louis, MO) and used at concentrations between 1 and 5 µg/ml. When nocodazole was added to cells on ice for 20 min, subsequent incubation at 37°C resulted in the complete depolymerization of all microtubules as detected by immunofluorescence microscopy of fixed specimens. N-ethylmaleimide (NEM) was purchased from
Sigma Chemical Co. Rabbit polyclonal antibody N10 against human milk
galactosyltransferase (GalTase) was kindly provided by Dr. E. Berger
(University of Zurich, Zurich, Switzerland). Rhodamine-labeled goat
anti-rabbit IgGs were purchased from Southern Biotechnology (Birmingham, AL).
DNA Constructs
The GFP chimeras used in this study (GFP-GalTase and GFP-KDELR)
are the same as those described in Cole et al. (1996a) Cells
HeLa and CHO cells from the American Type Culture Collection (Rockville, MD) were grown in flasks with DME supplemented with 10% FCS,
2 mM glutamine, and 150 µg/ml penicillin/streptomycin at 37°C in 5%
CO2. Cells replated onto No. 1 glass coverslips were transiently transfected with GFP chimera cDNAs by CaPO4 precipitation for 16 h, washed
once in PBS, and then incubated in complete medium for an additional 24 h
before viewing. Cells were imaged live on a temperature-controlled microscope at 37°C. CHO cells were used in the immunogold labeling experiment. All other experiments were performed using HeLa cells.
BODIPY-ceramide labeling of cells to visualize Golgi membranes was
performed as follows. Cells were incubated for 10 min at either 4 or 37°C
in serum-free Eagles Minimum Essential Medium (EMEM) and 25 mM
Hepes, pH 7.0, with 2-5 µM of BODIPY-ceramide (BODIPY FL C5-Cer/
C5-DMB-Cer; Molecular Probes Inc., Eugene, OR) (1,000× stock dissolved in methanol). Cells were then rinsed and incubated with EMEM
containing 0.68 mg/ml defatted-BSA (Sigma Chemical Co.) at 37°C for
~30-60 min before imaging with the 488-nm line of the confocal microscope or with a fluorescein filter set of a conventional fluorescent microscope as described below.
Electron Microscopy
Cryoimmunoelectron microscopy was according to Liou et al. (1996) Immunofluorescence Microscopy
Cells were fixed in 2% formaldehyde in PBS for 10 min at room temperature and then washed in PBS solution containing 10% FCS. The cells were
then incubated in a PBS solution containing primary antibody, 0.15% saponin, and 10% FCS for ~45 min. The primary antibody solution was
rinsed off and then replaced by rhodamine-labeled secondary antibody solution for 60 min. The coverslips were then washed in PBS serum. Coverslips were mounted on glass slides in Fluoromount G (Southern Biotechnology) for viewing on a fluorescence microscope.
Time-Lapse Imaging and Microscopy
HeLa cells grown on glass coverslips were sealed into a chamber fashioned out of silicon rubber (Ronsil; North American Reiss, Blackstone,
VA) placed on a glass slide and containing buffered medium with Oxyrase
(Oxyrase, Inc., Ashland, OH). The cells in Figs. 3 C and 4 were viewed
with a scanning confocal attachment (model MRC 600; Bio-Rad Labs,
Hercules, CA) attached to a microscope (model Axioplan; Carl Zeiss,
Inc., Thornwood, NY) with a 63× planapochromat lens (NA 1.4; Carl
Zeiss, Inc.). The 488-nm line of a krypton-argon laser was used with a 1 or
3% neutral density filter. Digital output was routed through a time and
date generator (model WJ-810; Panasonic Corp., New York), and single
frames were recorded on an optical memory disk recorder (model 3031F;
Panasonic). Cells in Figs. 2; 3, A and B; and 11, A and B, were viewed on a
confocal laser scanning microscope (model LSM 410; Carl Zeiss, Inc.)
equipped with a Kr/Ar laser and a 100× 1.4 NA planapochromat oil immersion objective. The GFP molecule was excited with the 488 line of the laser and imaged with a 515-540 bandpass filter. The time-lapse sequence
in Fig. 11 B was recorded using macros programmed with the Zeiss LSM
software package. In all other experiments, cells were viewed with a custom built inverted wide field microscope (model Eikoscope; Yona Microscopes, Columbia, MD). This microscope was equipped with a 63×, 1.4 NA objective and a cooled charge-coupled device (Photometrics, Tucson,
AZ) with a KAF 1400 pixel Kodak chip (Rochester, NY) for 12-bit image
detection. A 100-W mercury lamp was used as the light source. Neutral
density filters, excitation (485 nm band pass), emission (515 nm long pass),
and dichroic filters (fluorescence set XF32; Omega Optical Inc., Brattleboro, VT) were used to select the appropriate spectra for imaging GFP and BODIPY-ceramide. Biological Detection Systems imaging software (version 1.6, now Oncor imaging, Oncor Instruments, San Diego, CA) or
IPlab Spectrum was used to control image acquisition (Macintosh Quadra
800; Apple Computer Co., Cupertino, CA). Images were manipulated using IPlab Spectrum (Signal Analytics, Vienna, VA), NIH-Image software
(Wayne Rasband, Research Services Branch, National Institutes of
Health, Bethesda, MD), and Adobe Photoshop (San Jose, CA). Images
were printed with a Fujix Pictrography 3000 Digital Printer (Fuji Photofil
Co., Tokyo, Japan). None of the cooled CCD images collected and displayed had any saturated pixels. The dynamic range was 0-4,095 gray levels for the cooled CCD images. For the confocal images, the range was
0-255 gray levels. There was no overexposure in those confocal images
(Fig. 11, A and B), which were used to analyze Golgi blinkout and to fit a
diffusion constant since it clearly would have spoiled the quantitation.
Computer Simulation and Analysis of
Diffusive Transport
Fluorescence recovery after photobleaching (FRAP) was performed on a
Zeiss LSM 410 using the 488-nm line of a Kr/Ar laser (Cole et al., 1996a Diffusion was modeled assuming a random tubular network of variable
density that was defined by the measured fluorescence in a so-called reference state (i.e., long times after Golgi blinkout in BFA-treated cells, or before bleach in the FRAP experiments). The fluorescence in the cell was
assumed to evolve diffusively from an initial state (i.e., before blinkout in
BFA-treated cells, or immediately after bleach after FRAP) towards the
reference image. The initial and reference images, and background intensities to subtract, were supplied to a simulation program written in Fortran, which could produce output curves of fluorescence versus time for
any desired regions of interest. The basic principles used by this program
are all described in Appendix A. The time used in the simulation is converted to physical units by supplying the pixel size and an assumed Deff.
Curves using different trial values of Deff could then be plotted together
with actual data.
We have extensively tested this method under conditions where diffusive transport could be assumed (i.e., FRAP experiments) and values for
Deff could also be obtained from a dedicated FRAP instrument (Cole et al.,
1996a Localization of the GFP-Golgi Chimeras
Galactosyltransferase is a Golgi resident enzyme that functions in the remodeling of N-linked oligosaccharides attached to proteins moving through the secretory pathway.
By contrast, KDEL receptor is an itinerant Golgi protein,
which recycles KDEL-containing ligands passing through
the Golgi back to the ER (Lewis and Pelham, 1992
Confocal microscopy was used to compare the location
of GFP-GalTase and GFP-KDELR with other well-characterized Golgi markers, including GM130, a cis-Golgi matrix protein (Nakamara et al., 1995) and GalTase, a Golgi
enzyme enriched in medial-trans cisternae of Golgi stacks
(Berger et al.) (Fig. 2). Cells expressing the GFP-chimeras
were fixed and then labeled with primary antibodies to
GM130 or GalTase followed by rhodamine-conjugated
secondary antibodies. When such cells were imaged using
a confocal microscope, significant overlap in the distribution of green (GFP-chimera) and red (antibody) fluorescence was observed, giving rise to a merged yellow signal.
The subtle difference in staining pattern observed for
some of the proteins (for example, GFP-KDELR overlapped more with GM130 than with GalTase) is likely to
reflect differences in localization of these proteins to different sets of Golgi cisternae, as suggested in previous
studies comparing the distribution of Golgi markers using
confocal microscopy (Antony et al., 1992 Morphology and Dynamics of Golgi Membranes Labeled
with GFP Chimeras in Living Cells
To analyze the dynamic properties of Golgi membranes in
living cells, time-lapse recordings of HeLa cells expressing
the GFP-Golgi fusion proteins were performed. In Fig. 3,
A and B, each time point was composed of a set of confocal slices extending the depth of the cell so that the complete three-dimensional structure of the Golgi could be visualized. The data showed that the overall arrangement of
Golgi elements within the cytoplasm was relatively stable
over 15 min of imaging. However, local remodeling of
Golgi elements constantly occurred and involved the formation and/or detachment of thin tubule processes that interconnected adjacent Golgi elements. Many of the tubules
appeared to initiate more stable and thicker membrane
connections between Golgi elements (Fig. 3, arrows) and
were reminiscent of the tubules observed in electron microscopic studies that connect Golgi stacks into a continuous network (Tanaka et al., 1986 The large scale stability of Golgi structures contrasted
with the considerable plasticity of Golgi rims observed in
time-lapse sequences captured at high speed. Thin tubular
processes were found to extend rapidly, break off, or detach from the rims of Golgi stacks during any 5-min interval of imaging at 7-s intervals (Fig. 3 C). Tubule extension
and retraction frequently lasted 30-60 s and were a ubiquitous and prominent feature of Golgi dynamics.
Tubule activity of Golgi membranes labeled with GFP-Golgi proteins resembled in many respects those previously reported for the fluorescent lipid analogue NBD-ceramide (Cooper et al., 1990 Characteristics of Golgi Tubule Processes in
Untreated Cells
Time-lapse sequences captured at high speeds from cells
expressing GFP-KDELR revealed Golgi tubules to extend
rapidly, break off, and to continue to move out to the cell
periphery (Fig. 4 and Quicktime movie sequences at
http://dir.nichd.nih.gov/CBMB/pb4labob.htm). Analysis of the
sequences showed Golgi tubules moved along curvilinear tracks at average rates of 0.6 µm/s (Table I). They frequently extended 4-6 microns before retracting back or
detaching from Golgi elements on a time scale ranging
from 9-120 s. Detached tubules continued to move peripherally at rates of 0.6 µm/s before changing shape and direction. On some occasions, detached tubules curled up into a
ball and remained in this state until they disappeared from
view (perhaps as a result of fusion with the peripheral ER membrane system). Since detached tubules could be followed out to the periphery of the cell where they remained
visible for significant lengths of time and were observed on
either a confocal or conventional microscope system sampling a full depth of field, they were not an artifact arising
from imaging thin sections. Those tubule processes containing GFP chimeras that did not detach from Golgi elements sometimes initiated stable membranous connections with adjacent Golgi elements, as shown in Fig. 3, A
and B.
Table I.
Properties of Golgi Tubules in HeLa Cells
Expressing GFP-KDELR
; Mellman and
Simons, 1992
; Tanaka, 1996). How these distinct elements
organize and maintain themselves and act to efficiently
transport secretory and membrane components arriving
from the ER is of widespread interest.
). Unidirectional transport of protein
and lipid is thus achieved with no intermixing of donor and
acceptor compartments. The role of tubules in Golgi traffic has been given less attention, despite their prominence.
Both the cis- and trans-most cisternae of the Golgi complex are composed of extensive membrane tubule (50-
100-nm diameter) networks (Rambourg et al., 1979
; Saraste and Kuismanen, 1984; Sasaki et al., 1984
; Ladinsky
et al., 1994
; Clermont et al., 1995
), and tubule connections
between Golgi stacks frequently are observed in electron
micrographs (Tanaka et al., 1986
; Rambourg and Clermont, 1990
; Sesso et al., 1994
). Tubules can be rapidly generated by Golgi membranes in vivo and in vitro under various conditions (Cluett et al., 1993
; Weidman et al., 1993
;
Banta et al., 1995
; de Figueiredo and Brown, 1995
), and
time-lapse recordings of the Golgi complex labeled with a
fluorescent lipid analog, NBD-ceramide, have revealed tubule processes emerging from Golgi elements (Cooper et al.,
1990
). These observations indicate that tubule formation is
an inherent property of Golgi membranes.
; Lippincott-Schwartz et al., 1989
; Doms et al., 1989
) and inhibits
vesicle formation both in vivo (Donaldson et al., 1991
) and
in vitro (Orci et al., 1991
). This is likely due to BFA's inhibition of nucleotide exchange onto ADP-ribosylation factor (ARF), a low-molecular weight GTP binding protein
(Helms and Rothman, 1992
; Donaldson et al., 1992b
), which
prevents assembly of cytosolic coat proteins (including
COP I components) onto target membranes (Orci et al.,
1991
; Klausner et al., 1992
). At the same time, extensive retrograde transport of Golgi components to the ER mediated by growth of Golgi tubules occurs with BFA, leading to the complete loss of Golgi structure (Lippincott-Schwartz
et al., 1990
). Since a normal retrograde pathway from the
Golgi back to the ER exists (Pelham, 1991
; Jackson et al.,
1993
; Stinchcombe et al., 1995
), it has been suggested that
transport into the ER induced by BFA represents enhanced trafficking through this retrograde pathway as a
result of nonselective transport into it of Golgi protein and
lipid (Klausner et al., 1992
; Lippincott-Schwartz, 1993
). How
trafficking in BFA-treated cells differs from normal retrograde traffic, what role tubules play in mediating such traffic, and how its perturbation by BFA leads to Golgi disassembly are important unanswered questions.
) to examine the dynamics of
the Golgi complex in vivo and how it is perturbed by BFA.
The GFP chimeras provide useful probes of Golgi membrane morphology and dynamics: they localize almost exclusively to Golgi membranes and their diffusional mobility is rapid. By imaging Golgi membranes over time, we
show that thin membrane connections between adjacent
Golgi elements continuously remodel Golgi structure and
that membrane tubules readily pull out along microtubules and detach from Golgi rims. In BFA-treated cells,
tubules formed at a more rapid rate and failed to detach
from Golgi structures. A dynamic tubule network was generated and persisted for 5-10 min until rapidly emptying protein and lipid contents into the ER within 15-30 s with
no Golgi structure remaining. The directionality of the redistribution process implied Golgi membranes to be at a
higher free energy state than ER membranes, while its
speed (too fast to be explained by simple diffusion) was
consistent with tension-driven membrane flow.
; Bloom et al., 1991
) and result in rapid and unidirectional fluid transport (Batchelor, 1967
). Spreading of
a film on an air-water interface, wetting of a dry solid substrate by a film, or osmotically driven solvent flow through
channels that exclude solute are typical examples of flow
(de Gennes, 1985
; Probstein, 1994
). In the context of
membranes, flow results from forces either chemically or
mechanically produced, which in the context of membranes
are conviently expressed as surface tension gradients
(force/area) (Probstein, 1994
). The existence of tension-driven membrane flow between Golgi and ER compartments suggested by our findings raises fundamental questions about the basic physical-chemical parameters of the
Golgi-ER membrane system and the role and regulation
of membrane tubules.
Materials and Methods
and used the S65T
variant of GFP (Heim et al., 1995
). Briefly, the GFP coding region was
placed downstream of coding sequences containing human galactosyltransferase or a mutant form of the human homologue of the yeast ERD2
protein, ELP1 (Hsu et al., 1992
), also known as KDELR. GFP-GalTase
contains amino acids 1-60 of galactosyltransferase, including the NH2-terminal cytoplasmic tail, transmembrane domain, and 17 amino acids of the
luminal domain fused to full-length GFP. The mutant form of KDELR-GFP used in this study was generated by mutagenizing the aspartic acid to
an asparagine residue at position 195 of ELP1 (analogous to the mutation
at position 193 in ERD2 described in Townsley et al., 1993). This mutation
caused KDELR-GFP to be more tightly localized to the Golgi complex,
with less ER staining compared with the wild-type protein.
.
CHO cells expressing GFP-GalTase were fixed in the culture dishes by
adding 1 vol of 4% formaldehyde and 0.2% glutaraldehyde to the culture
medium for 10 min at room temperature. Fixation was continued for an
additional 90 min after diluting the above solution with fresh medium 1:1.
Cells were carefully scraped from the dish with a rubber policeman, rinsed
in phosphate buffer/0.15 M glycine, and embedded in 10% gelatin. Gelatin blocks were infused with 2.3 M sucrose overnight and then frozen in
liquid nitrogen. A cryoultramicrotome (Reichert Ultracut S) was used to
cut thin cryosections (60 nm) that were collected on pyoloform-coated
nickel grids. Immunogold labeling on the grids was performed using a rabbit polyclonal antibody to GFP (CLONTECH Laboratories, Palo Alto,
CA) at 1:500 dilution, and protein A conjugated with 15-nm gold particles
(Biocell Labs, Carson, CA). An electron microscope (model CM10; Phillips Electronic Instruments, Mahwah, NJ) was used to examine and photograph specimens.
Fig. 3.
Tubule connections
and extensions of the Golgi
complex. (A and B) A time
series of images from HeLa
cells expressing GFP-GalTase (A) or GFP-KDELR
(B) were collected at 0, 10, and 15 min at 37°C on a confocal microscope. Each image represents an overlay of a set of confocal slices extending the depth of the cell.
Short arrows point to thin
membrane connections initiating more stable membrane
continuities between Golgi
elements, while long arrows point to areas of detachment.
(C) Single images with the
confocal pinhole wide open
were collected at 7-s time intervals in GFP-KDELR- expressing cells. Arrows point
to thin tubule that rapidly extended off of Golgi rim. Bars,
3 µm.
[View Larger Version of this Image (124K GIF file)]
Fig. 4.
Formation and detachment of Golgi tubules in
untreated cells. GFP-KDELR-
expressing HeLa cells were
imaged at 3-s time intervals at 37°C on a confocal microscope with the pinhole partly
closed and brightness level
increased for optimal imaging of tubules (at this brightness level GFP intensity
within Golgi elements was
saturated). Tubules pulled
off from Golgi rims, extended into the cell periphery, and often detached from
Golgi elements. Detached Golgi tubules continued to
move peripherally. Bar, 3 µm.
See Quicktime movie sequence at http://dir.nichd.nih.
gov/CBMB/pb4labob.htm.
[View Larger Version of this Image (189K GIF file)]
Fig. 2.
Double labeling of GFP chimeras with Golgi markers
using immunofluorescence microscopy. GFP-GalTase or GFP-KDELR expressing HeLa cells were fixed, permeabilized, and labeled with antibodies to the indicated Golgi proteins followed by
secondary antibodies coupled to rhodamine. GFP fluorescence is
shown on the left, rhodamine labeling in the middle, and the
merged images in the right panels. Yellow indicates regions of
overlap. Bar, 3 µm.
[View Larger Version of this Image (37K GIF file)]
Fig. 11.
Evidence for membrane flow from Golgi to ER: diffusive recovery from photobleach contrasted with the time course of Golgi blinkout. (A) Three confocal images showing photobleaching and recovery of GFP-GalTase in the ER in cells treated with BFA for 1 h.
The left panel is the prebleach image, the middle panel is just after the bleach, and the right panel is after recovery. The bleached region
is outlined in dashed lines. The fluorescent intensities within the boxed ROIs labeled 1, 2, and 3 during recovery are plotted as symbols
to the right (diamonds, crosses, and pluses, respectively). The smooth curves are simulations with Deff of 2.5 × 109cm2/s as explained in
the text and Appendix A. The dashed curves are the same simulation assuming Deff of 5.0 × 10
9cm2/s. Note that even though each ROI
displayed a different recovery curve, a single Deff of 2.5 × 10
9cm2/s in the simulations could effectively account for all the experimental data. (B) The same cell as in A was imaged during Golgi blinkout after addition of BFA. The two confocal images correspond to onset of Golgi blinkout and after the redistribution into the ER is complete. The fluorescent intensities within the boxed ROIs labeled 1, 2, and 3 during Golgi blinkout are plotted to the right as symbols (pluses, crosses, and diamonds, respectively). Numerical simulations began with the fluorescent density field shown in the left panel and assumed diffusive transport toward the field in the right panel. The
smooth curves in the graph show the simulated intensity assuming Deff of 2.5 × 10
9cm2/s, whereas the dashed curves show the simulated intensity assuming Deff of 5.0 × 10
9cm2/s. Note the latency period of the experimental data in relation to the simulated curves and
the more sigmoidal rise. (C) Three cooled CCD images of a GFP-KDELR-expressing cell at the beginning of Golgi blinkout (left), 7.4 s
later (middle), and the final time point 37 s later (right). Fluorescent intensity values of the four ROIs shown were plotted as a function
of time in BFA. Numerical simulations ran from the first panel toward the third as in B. Diffusion constants for each ROI that best fit
the data are shown. Bars (A and C), 10 µm.
[View Larger Versions of these Images (133 + 15K GIF file)]
).
The outlined box was photobleached at full laser power (100% power,
100% transmission), and recovery of fluorescence was monitored by scanning the entire cell at low laser power (30% power, 0.3% transmission) in
10-s intervals. Negligible bleaching occurred while imaging the recovery
process at low laser power.
). In another study performed in this lab (Ellenberg et al., 1997
), diffusion of ER proteins was analyzed using a traditional FRAP approach in
which a thin strip was bleached across the cell. Deff was determined for
large numbers of cells both by the traditional approach of fitting to an
equation describing one-dimensional diffusion and by matching predicted curves produced by the simulation program with actual data. The resulting Deff determined in the same cell using the two methods were extremely similar.
Results
). Previous work has demonstrated that addition of the GFP tag
to these proteins does not interfere with Golgi targeting of
these proteins or with ligand-induced recycling of KDELR
(Cole et al., 1996a
). GFP-tagged galactosyltransferase
(GFP-GalTase) and KDEL receptor (GFP-KDELR) were
both shown to reside predominantly in juxtanuclear Golgi-like structures, with GFP-KDELR also found in small
amounts in the ER (Cole et al., 1996a
). To further analyze the Golgi location of these chimeras, we used immunogold
electron microscopy, and confocal microscopy of double-labeled specimens. Immunoelectron microscopy using thin,
frozen sections labeled with polyclonal antibodies to GFP
followed by secondary antibodies coupled to 15-nm gold
revealed the ultrastructural distribution of the chimeras.
As shown in Fig. 1, A-C, for GFP-GalTase, nearly all of
the gold particles were restricted to the Golgi complex and
were mostly found associated with stacked cisternae. No
significant gold labeling of plasma membrane or nuclear envelope was detected. In cells expressing GFP-KDELR
(Fig. 1 D), a similar localization of gold particles to Golgi
stacks was observed, but occasional gold particles were
also found over the ER.
Fig. 1.
Localization of
GFP-GalTase by immunogold microscopy. Gallery of
images from cryosections of
CHO cells expressing GFP-GalTase (A-C) or GFP-KDELR (D) that were immunostained with anti-GFP
antibody and 15-nm colloidal
gold protein A. Note that
multiple cisternae within
Golgi stacks are specifically
labeled with gold particles. Nu, nucleus; Pm, plasma
membrane. Bars, 0.2 µm.
[View Larger Version of this Image (174K GIF file)]
; Nilsson et al.,
1993
; Shima et al., 1997
). Altogether, the above results suggest that the majority of GFP-tagged GalTase and KDELR molecules expressed within HeLa or CHO cells reside
within Golgi stacks and that they exhibit overlapping distributions among Golgi cisternae.
; Rambourg and Clermont, 1990
).
), which localizes to Golgi
stacks and the TGN (Lipsky and Pagano, 1987
; Pagano et al.,
1989
). Imaging of living cells with the lipid analogue additionally revealed, however, submicron particles (previously described as secretory vesicles leaving the TGN) that
moved outward from the Golgi region to the plasma membrane (Cooper et al., 1990
). GFP-tagged KDELR and
GalTase described here were never observed in outward
moving particles or vesicles (only tubules) and never appeared on the plasma membrane. Instead, these proteins
remained predominantly localized to Golgi membranes
with small amounts found in detached tubules and the ER.
The curvilinear path and rate of movement of Golgi tubules suggested they were transported along microtubules.
Consistent with this, Golgi tubule processes were not observed in cells treated with the microtubule-disrupting
agent nocodazole (not shown). Since Golgi tubules appeared to move peripherally along microtubules, a plus
end-directed microtubule motor, possibly kinesin (Vale et
al., 1985; Lippincott-Schwartz et al., 1995
), could be associated with their membranes to power such movement.
Proliferation of Golgi Tubules during BFA Treatment
The steady-state dynamics of Golgi membranes containing
GFP chimeras described above was profoundly altered
upon treatment of cells with BFA. BFA prevents the binding of peripheral COP I proteins onto Golgi membranes
and results in Golgi membrane tubulation and redistribution into the ER (Klausner et al., 1992). Time-lapse imaging of BFA-treated cells revealed that the rate of tubule formation dramatically increased within 4-5 min after adding
the drug (Fig. 5 and Table I). BFA-induced Golgi tubules were motile, extending/retracting and sometimes appearing to bifurcate (Fig. 5). Their overall appearance and
properties were similar to those found in normal cells (Table I), except that they did not detach from the Golgi and
extended enormous lengths (up to 20 µm) into the cytoplasm. That GalTase and the fluorescent Golgi lipid analogue BODIPY-ceramide (Pagano et al., 1991
) colocalized within the same tubules in BFA-treated cells (Fig. 6) suggested extensive mixing of Golgi lipids and proteins within
these structures.
Delayed and Rapid Redistribution of Golgi Membranes into the ER in BFA-treated Cells
The Golgi tubule network generated during BFA treatment persisted for several minutes. Then, very abruptly,
the network disappeared and GFP chimera fluorescence
redistributed into the ER (Fig. 5 and Quicktime movie sequence at http://dir.nichd.nih.gov/CBMB/pb4labob.htm.). Emptying of GFP chimera fluorescence into the ER in
some cases took only 15 s. In the cell shown in Fig. 5, for
example, fluorescence within the Golgi tubule network at
8 min 33 s was completely redistributed into the ER (including the nuclear envelope) by 8 min 57 s. Although redistribution of Golgi into the ER during BFA-treatment is
well known (Doms et al., 1989; Lippincott-Schwartz et al.,
1989
), the two step process of Golgi tubule network formation followed by sudden, rapid delivery of Golgi membrane into the ER was unexpected.
Golgi redistribution into the ER occurred at different times in different cells (Fig. 7 A) but was always a sudden, explosive event that we called Golgi "blinkout." Within a population of over one hundred cells, Golgi blinkout usually occurred 4 to 8 min after BFA was added and had a duration of 15-60 s during which Golgi-localized fluorescence dispersed into the ER (Fig. 7 B). Significantly, the number of Golgi structures in a population of cells treated with BFA decreased exponentially in time (after a latency period of about 4 min) (Fig. 7 C), resembling a first-order process (i.e., radioactive decay). This suggested that entry of BFA-treated Golgi membranes into the ER system is likely to involve a unique fusion event or entry site rather than targeting and fusion of a mass of tubules or vesicles.
Golgi membranes labeled with BODIPY-ceramide also redistributed into the ER in BFA-treated cells by a rapid and discrete process (Fig. 8 A). The onset and duration of Golgi blinkout in these cells was indistinguishable from that of cells expressing the GFP-Golgi protein chimeras. For both, blinkout usually occurred between 4 and 8 min after adding BFA and lasted only 15-60 s (Fig. 8 B). In addition, Golgi structures in the population of cells disappeared exponentially in time, consistent with a unique fusion event triggering the redistribution process (Fig. 8 C). As found for the GFP-Golgi protein chimeras, very little BODIPY label was left concentrated in Golgi structures after this redistribution (Fig. 8 A), with the label instead found distributed throughout the ER system. In cells stained with higher concentrations of BODIPY-ceramide, however, a Golgi remnant sometimes remained and presumably corresponded to the trans-Golgi network, which does not redistribute its membranes into the ER with BFA (Lippincott-Schwartz, 1991). These results suggest that both Golgi lipid and protein are delivered at equivalent rapid rates into the ER upon initiation of a distinct event (possibly fusion of a single Golgi tubule with the ER) in BFA-treated cells.
Golgi blinkout was temperature dependent and NEM sensitive. At temperatures below 30°C tubules proliferated, but Golgi redistribution into the ER rarely occurred within 30 min of imaging (data not shown). In the presence of NEM (2 µg/ml added 2 min after BFA), tubules formed but quickly lost their ability to move, and no redistribution of Golgi membrane into the ER occurred (data not shown).
Effects of Microtubule Disruption and Golgi Fragmentation on the Process of Golgi Blinkout
Cells treated with nocodazole before addition of BFA
showed no induction of Golgi tubules (Fig. 9), consistent
with a microtubule requirement for peripheral extension
and movement of these elements. In addition, the interval
of time preceding Golgi blinkout dramatically increased
and occurred anytime between 10 and 50 min of BFA treatment. The duration of individual Golgi blinkouts, however,
was unchanged. This is illustrated in Fig. 9 (see also Quicktime movie sequence at
http://dir.nichd.nih.gov/CBMB/pb4labob.htm.), where GFP-GalTase fluorescence associated with the Golgi complex was relatively constant for 36 min of BFA treatment and then completely redistributed into the ER during the next 1 min. This result suggests that
extension of Golgi tubules along microtubules serves to increase the probability of fusion between Golgi and ER
membranes. Once fusion between these two organelles is
initiated (which can occur in the absence of Golgi tubule
extension since ER membranes are distributed throughout the cytoplasm), the Golgi rapidly and completely empties
into the ER.
Within single cells whose Golgi elements were scattered/
fragmented and not obviously interconnected, distinct
BODIPY-ceramide or GFP-GalTase containing Golgi elements disappeared at different time points after BFA treatment. This is shown for BODIPY-ceramide in the cell shown
in Fig. 10, where 22 images (comprising the time course of
BFA-induced Golgi blinkout) were analyzed. The distribution of Golgi elements at the start of the experiment is
shown schematically on top. The three panels on the bottom show three time series (direction of time is left to
right, 2:40-6:09 min) correlating to three vertical line scans
through the data set. The intensity of the BODIPY-ceramide during the time series was mapped to a color
lookup table shown at the upper right, with the most intense signal colored purple and blue, and least intense colored red and yellow. Bright BODIPY-ceramide structures
(correlating to discrete Golgi elements) disappeared suddenly at different time points upon BFA treatment, suggesting that multiple Golgi blinkouts occur within a single
cell when membranes from one Golgi element either fail
to connect or are unable to connect to others (i.e., during
microtubule disruption).
Evidence that a Tension-driven Membrane Flow Drives Golgi Redistribution into the ER
The finding that BFA-treated Golgi membranes are rapidly delivered into the ER over a 30-s to 1-min time interval in a probabilistic manner and that microtubules increase the probability (but not the speed) of redistribution
is consistent with blinkout being initiated by a single fusion event between a Golgi tubule and the ER, rather than
by massive budding and fusion of vesicles. Redistribution
of Golgi membrane under this model would occur by lateral membrane movement across the newly formed site of
ER-Golgi continuity and then spreading of Golgi membrane across the ER. The unidirectionality of this process,
with the entire Golgi body absorbed into the ER rather
than the two compartments mixing while retaining their
respective areas, indicates that free energy is lost upon
Golgi membrane redistribution. This finding, together with
the observation that lipid and protein move at identical rapid rates into the ER (despite the fact that lipid typically diffuses 10 times faster than protein) raises the question
whether Golgi material moves into the ER diffusively or is
carried by a tension-driven flow. The latter process is common in many continuous fluid systems having free energy
differences. A typical example is the spreading of detergent on an air-water interface. In that case, a lateral tension gradient (force/area) arising from unequal concentration of detergent at the air-water interface causes a flow
that spreads the detergent much faster than diffusion (Probstein, 1994).
To address whether tension-driven membrane flow contributes to the Golgi redistribution process required quantitative analysis of digitized images of the GFP-protein chimeras collected during blinkout. An effective diffusion constant Deff for the GFP-protein chimeras during the redistribution process can be calculated from such images (Appendix A). This Deff can then be compared with the Deff measured from photobleaching experiments of the same protein species in the ER when only diffusive transport is occurring. If flow into the ER were occurring during the redistribution process, then Deff for the spread of GFP-protein chimeras through the ER at blinkout should be greater than Deff measured during recovery after photobleaching performed with the chimera equilibrated within the ER (after long-term BFA treatment).
A method was developed for calculating Deff from photobleaching and Golgi redistribution experiments that accounts for the relative density and geometry of the ER in the actual cell being imaged. The mathematics and theory for this approach are discussed in Appendix A, and its application is outlined in Materials and Methods. It is instructive to contrast our methodology with the conventional method for determining Deff using FRAP. In FRAP, a narrow (~2-µm) strip is rapidly bleached across a fluorescent sample, and fluorescence recovery into the strip is fit to an analytically derived function describing one- dimensional diffusion from an infinite medium into a hole. Here, we simulated the diffusive recovery of the optical intensity profile within the entire cell after photobleaching and made no assumptions about the shape and size of the bleached region or whether partial recovery occurred during the course of the bleach. The experimental image at any time point was evolved forward under the assumption that it was relaxing diffusively towards the prebleach intensity pattern. Assuming lateral diffusion alone is governing the fluorescence recovery in the experiment, a single Deff should describe all experimental regions of interest (ROIs) that are plotted from the experiment. This provides an immediate internal check on the quality of the algorithm used to simulate diffusive transport. During Golgi redistribution into the ER in BFA-treated cells, if fluorescence transfer was occurring by lateral diffusion then simulations using Deff obtained from photobleaching recovery experiments should reproduce it as well as for the photobleaching recovery experiment.
The above method was first used to calculate Deff from
photobleach recovery experiments in cells with GFP-GalTase completely redistributed into the ER by BFA well
after blinkout, where only diffusive transport should be
occurring. To obtain a Deff for diffusional recovery in this
experiment, theoretical curves were simulated assuming a
diffusive process and matched to the experimental data by
adjusting only the diffusion constant used in the simulation. As shown in Fig. 11 A, a single Deff (2.5 × 109 cm2/s ± 0.5) reasonably fit the experimental data for all ROIs in the cell shown, even though each ROI displayed a different recovery curve reflected by the density of ER in that
region. This Deff fit experimental photobleaching data obtained from numerous cells using hundreds of different
ROIs and was close to the same Deff measured previously
for GFP-GalTase in the ER by conventional FRAP methods (e.g., 2.1 × 10
9cm2/s ± 0.2) (Cole et al., 1996a
). For
comparison, simulated curves for the ROI in Fig. 11 A
using Deff of 5 × 10
9cm2/s are shown as dashed lines in
the graph. We have used this algorithm extensively to
model diffusive recovery in another study and found good
matches to diffusion coefficients generated using more traditional slit photobleaching approaches (Ellenberg et al.,
1997
).
Fig. 11 B shows a similar analysis after fluorescence redistribution into the ER of GFP-GalTase in the same cell
as in Fig. 11 A at the time of Golgi blinkout. The time
course of the redistribution was followed by plotting the
intensity averages over several strategically placed ROIs.
Shown on the same graph are curves from computer simulations using Deff of 2.5 × 109cm2/s or 5 × 10
9cm2/s,
which start from the first time shown and model the redistribution as diffusion (see Appendix A). It is assumed that
when the numerical integration begins, all the GFP marker
is in contact with the ER and free to diffuse throughout
this compartment. In contrast to the case for the photobleach recovery experiment above, the experimental
data points from Golgi blinkout could not be described by
a single Deff . Moreover, many of the ROIs examined had
a latency period in relation to the simulated curves and a
more sigmoidal rise, suggestive of a wave of material progressing outward as a flow rather than diffusive transport.
This type of kinetic analysis of Golgi blinkout was performed on over 10 cells with similar results. Data from a
cell expressing GFP-KDELR is shown in Fig. 11 C. The
simulated Deff that best fit the experimental data to each
ROI are indicated (despite each having a latency period
and more sigmoidal rise compared with the simulated diffusion curves, though less than in Fig. 11 B). For the two
ROIs to the right of the Golgi, Deff was slightly less than
Deff measured in the photobleaching experiment for GFP-KDELR. For the ROIs below the Golgi, however, Deff was
three to five times this value.
The disparity in diffusion constants needed to fit different ROIs in Golgi blinkout experiments was not explained by assuming delayed fusion of different regions of the Golgi complex with the ER. In Fig. 11 C, for example, one might assume that fusion between Golgi and ER first occurred at a tubule in the bottom of the figure, so as to be closer to the ROI that ostensibly required a large Deff, and further from those that were fit with a small Deff. However, under this scenario facilitated transport or flow would need to be invoked since it is impossible to drain the Golgi by diffusive transport through only a few tubules in a short time interval (see Discussion), while flow through one or a few tubules would do the job. Also, placing the release point low in the figure would increase the Deff determined for the upper ROI by a factor approximately four (the distance to be traveled is roughly doubled), thus making Deff again too large. The problems with a purely diffusive model would not be alleviated by supposing that other points of fusion occurred later since material definitely has moved between the first two images and the less time available for that to occur pushes the inferred Deff value upward. These results indicate that simple diffusive models cannot explain the rate Golgi membrane redistributes into the ER during BFA treatment (i.e., Deff are too high), whereas flow-assisted membrane transport processes can.
Golgi Membrane Tubules
Ultrastructural studies have shown tubules (with diameters of 50-100 nm and variable length) to be an inherent
feature of Golgi membranes. Both the cis- and trans-cisternae are composed of extensive tubule networks, and tubule bridges frequently connect different stacks or loop
back to cisternae within the same stack (Tanaka et al.,
1986; Rambourg and Clermont, 1990
; Weidman et al., 1993
).
Moreover, circular profiles in stereopairs of thick specimens often correspond, not to vesicles, but to cross sections of numerous narrow tubules extending off from
edges of Golgi cisternae (Clermont et al., 1995
). What
studies of fixed cells cannot reveal is the dynamic nature of
these tubules, including how they arise (i.e., by vesicle-vesicle fusion, periplasmic fusion, or extension/detachment from cisternae [Rothman and Warren, 1994
]), their lifetime, and their fate in vivo. The most striking feature of
untreated Golgi membranes studied in living cells with
GFP-tagged Golgi proteins was the continuous extension
of membrane tubules from Golgi rims at rates on the order
of 0.6 µm/s along microtubules, as well as their detachment. Such tubules are a prominent, ubiquitous feature of
Golgi dynamics and appear to play a dual role both in interconnecting adjacent Golgi elements and in transporting membrane out from the Golgi in normal cells.
In the latter capacity, detached tubules containing GFP-Golgi proteins moved significant distances into the cell periphery before curling up and then often disappearing
from view. This suggested they might have a carrier function in some membrane transport pathway. KDELR and
GalTase are never transported to the cell surface but do
recycle to the ER (Pelham, 1991; Cole et al., 1996b
), which
exists as a peripheral membrane network throughout the
cell (Terasaki et al., 1986
). Assuming the GFP tag did not
alter this property, Golgi tubules carrying these proteins to
the cell periphery could represent retrograde transport intermediates. Since BFA augments but does not otherwise
alter the morphological properties of Golgi tubules, our
observations are consistent with the supposition that BFA
treatment merely accentuates a normal constitutive membrane cycling pathway. Interestingly, GFP-KDELR was
observed more often in the peripherally extending Golgi
tubules than GFP-GalTase (data not shown), suggesting that KDELR recycles to the ER more frequently than GalTase.
The other function of tubules is to connect Golgi elements and thereby to facilitate the well-established capacity of the Golgi body to remodel itself. Such processes are
likely to be important for Golgi reassembly after mitosis
(Warren, 1993) and after removal of BFA (Lippincott-Schwartz et al., 1990
) or other agents that lead to Golgi
fragmentation. The high mobility of Golgi resident proteins
within Golgi membranes revealed by photobleaching studies (Cole et al., 1996a
) enables resident components to diffuse quickly between stacks that have become interconnected by tubules and plausibly facilitates the amalgamation
of Golgi elements.
Regulation of Tubule Formation
Given the dual roles of tubules in Golgi dynamics and
their proliferation in response to BFA, what can be said
about their regulation? To fabricate a tubule or vesicle
from flat bilayer without an external force requires increasing the outer leaflet area at the expense of the inner
one. Most directly this can occur by flipping lipids from inner to outer leaflets (Mui et al., 1995) or inserting new
moieties into the outer leaflet (Fuchs et al., 1995
). Alternatively, one can increase the effective area per head group
in the outer leaflet by increasing the charge via phosphorylation, by cleaving one of the acyl chains by a phospholipase, by recruiting wedge-shaped lipids to the bud site, or
merely via unequal electrostatic screening of the two leaflets (Chou et al., 1997
). Since tubules proliferate in BFA-treated cells where peripheral "coat" proteins (including
COP I proteins) are dissociated from Golgi membranes, such proteins may play an ancillary and perhaps a regulatory role rather than a structural one in tubulation. COP I
proteins, for example, might act like cytosolic "receptors"
for membrane-bound proteins that are recruited into the
retrograde pathway (Pelham, 1994
), and in so doing could
couple with any one of the many mechanisms for inducing
membrane curvature.
The extension of Golgi tubules appears to be a relatively
simple process once the mechanism for supplying membrane curvature is at hand. Our results show that microtubules are required and that the membrane tubules move at
speeds 0.6 µm/s towards the plus ends of microtubules.
Thus, a kinesin-like motor is likely involved (Lippincott-Schwartz et al., 1995), and the mechanisms by which the
tubule components of the ER are extended along microtubules (Dabora and Sheetz, 1988
; Allan and Vale, 1994
)
provide a possible model for Golgi tubules. The motor
proteins may simply guide the Golgi membrane extensions
and overcome the resistance of cytoplasmic obstacles. An
alternative possibility is that the microtubule motor force
itself creates tubules from a free membrane with no preferred curvature. Given a bending modulus in the range of
typical in vitro experiments of ~10 times thermal and
force of ~4 pN appropriate to kinesin, radii of ~50 nm are
implied by the balance of forces (Dai and Sheetz, 1995
;
Sheetz and Dai, 1996
). Arguing against this interpretation,
however, are the appearance of tubules in the correct size
range in in vitro experiments (Cluett et al., 1993
) and the
various biochemical means the cell has for the regulation of membrane curvature.
Tubulation in Response to BFA
An immediate target of BFA is ARF, which in physical
terms is an energy-driven assembly-transport system for
supplying COP I to membranes (Donaldson et al., 1992a;
Orci et al., 1993
; Palmer et al., 1993
; Rothman and Wieland,
1996
). When nucleotide exchange onto ARF is inhibited
by BFA, COP I proteins are quickly depleted from Golgi
membranes (Donaldson and Klausner, 1994
). In response, Golgi tubules proliferate, they are longer, and they do not
so readily detach from the Golgi complex. Ultimately, fusion with the ER occurs and the Golgi disappears. Given
this mechanism of BFA action, either the absence of COP
I unblocks processes that cause leaflet area imbalance and
hence tubules, or the tubulation is an autonomous downstream consequence of the perturbation in ARF cycling
(for example, as a result of ARF's effect on phospholipase D metabolism [Brown et al., 1993
; Cockroft et al., 1994;
Ktistakis et al., 1996
]). Both scenarios could impact protein sorting processes in the Golgi system.
If peripheral "coat" proteins served as a filter or aggregator to facilitate recycling of specific proteins, then there must be at least two populations of transport structures in untreated cells (for recycling components versus forward moving cargo), the contents of which would indiscriminately mix and distribute into tubules in the presence of BFA. Another function of such coat proteins suggested by BFA treatment is in promoting the detachment of tubules. This would be another way in which the integrity of the Golgi body is protected, by severing potential links to other organelles. Whether this property has any structural relation to the mechanism that promotes tubule formation remains to be seen.
Golgi Membrane Resorption into the ER
Golgi elements that were extensively interconnected by membrane tubules during the first 5 to 8 min of BFA treatment rapidly emptied protein and lipid into the ER in a process (called blinkout) usually lasting only 30 s. Golgi structures within a large population of cells were observed to undergo blinkout at distinct time points as in a first order or exponential process. This suggested that Golgi blinkout within individual cells was initiated by a single stochastic event, possibly fusion of a single Golgi tubule with the ER rather than multiple fusion events over an extended period.
The interval before blinkout was greatly increased (to between 10 to 50 min) when Golgi tubule extension was inhibited by depolymerization of microtubules by nocodazole. Once fusion between the ER and Golgi was initiated, however, redistribution still occurred as a very rapid process with Golgi protein and lipid emptying into the ER in less than one minute. This result indicates microtubules are not critical to the redistribution or blinkout phenomenon, although they increase its probability of occurrence, presumably by providing tracks for Golgi tubules to extend peripherally, where they have a greater chance of contacting the ER (which also extends peripherally along microtubules).
Since the blinkout process appeared identical whether
viewed with a protein or lipid marker and in neither case
was there any significant Golgi remnant structure, we infer
that Golgi membranes were absorbed (i.e., moved unidirectionally) into the ER after ER-Golgi fusion, rather than
that the two compartments merely mixed but retained their
respective areas (see Fig. 12). Various estimates put the
surface area of the Golgi at 20% of that of the ER system
(Griffiths et al., 1989), so that if a significant fraction of
Golgi structure remained intact after BFA-induced redistribution, a concentration of fluorescent material (representing 20% of total fluorescent signal) would still be visible
in the Golgi region as material mixed uniformly throughout the ER-Golgi system. Since no such residual concentration of GFP fluorescence was found, the results suggest
that the entire Golgi body is absorbed into the ER unidirectionally rather than mixing its membranes one-for-one
with ER membranes and retaining its structural integrity. Consistent with this, ER markers in BFA-treated cells also
showed no accumulation of fluorescent signal in the Golgi
region (data not shown). In addition, recognizable Golgi
stack-like structures in BFA-treated cells are not observed by electron microscopy (Fujiwara et al., 1988
; Lippincott-Schwartz et al., 1989
).
The unidirectionality of Golgi transfer into the ER and
its irreversibility in BFA-treated cells suggested it is a
thermodynamically favored process with free energy released. The simplest model for this is that the ER provides
a lower energy environment for membrane protein and
lipid than the Golgi system. The specific chemical basis for
such an energy difference between ER and Golgi membranes is unknown. One possibility is that the work required to "pump" Golgi-destined material up in energy is
supplied by the peripheral "coat" system, which concentrates membrane proteins exported from the ER and packages them into transport structures (Balch et al., 1994;
Schekman and Orci, 1996
). Such a system would also likely
generate a specific lipid composition within these structures
(Warren et al., 1975
).
Tension-driven Membrane Flow from Golgi to ER
Given that there appears to be chemical potential or free
energy differences between ER and Golgi membranes
that lead to unidirectional transport when these membranes fuse upon BFA treatment, one can ask whether
such transport occurs diffusively or is driven by a membrane tension flow. Free energy differences do not per se give rise to flow; a diffusion and sticking mechanism could
also account for irreversible absorption of one compartment by another. Flow results from forces, which in the
context of membranes are surface tension gradients (force/
area) (Probstein, 1994). One straightforward mechanism
for establishing tension gradients is to remove material
from membranes in one region and add it in another, as
has been reported to occur at the plasma membrane (Dai
and Sheetz, 1996). Chemical physics supplies a number of other situations involving multiple phases in contact such
as wetting and spreading of a surfactant along an interface
where flow-based transport exists and is more rapid than
diffusion (de Gennes, 1985
; Probstein, 1994
).
Our evidence for tension-driven membrane flow in the
ER-Golgi system is circumstantial; we have not directly
measured a velocity for Golgi membrane transport into
the ER. To favor a diffusive explanation as much as possible in our analysis of Golgi redistribution into the ER during BFA treatment, we assumed simultaneous connection of all parts of the Golgi to the ER. In one case (see Fig. 11
C), the fluorescence intensity of GalTase-GFP in various
ROIs within the ER all started to rise at the same time
during Golgi blinkout, but the Deff required to fit the overall rise varied by a factor of 10 among the ROIs and for the
fastest was a factor of 4-5 times greater than the diffusion
constant measured by FRAP. One might argue that in this
case it was the lipid diffusion constant (plausibly 5-10 times
larger than the GFP-KDELR value of 4.5 × 109cm2/s)
that governed the blinkout time, and that the fluorescent protein was swept along. In another case (see Fig. 11 B),
however, Deff was not so great. The experimental data in
this case could not be fit well by simple diffusion since it
had a latency period followed by a sigmoidal rise in intensity values resembling that of a wave or front of fluorescent material moving across the ER. Such a sigmoidal profile would be expected from flow-assisted transport. The
complex geometry of the ER was not responsible for these
unusual time courses since our methodology (see Appendix A) was able to quantitatively simulate photobleach recovery in the same cells and obtain the same diffusion constants that were measured previously by FRAP (Cole et al.,
1996a
).
If one speculates about how connections are made between the Golgi and ER at the time of Golgi blinkout, there
are circumstances where diffusion may be ruled out on
purely theoretical grounds (see Appendix B). Consider
two organelles connected by a single tubule of diameter,
d = 0.1 µm, and length, L = 3 µm, which drains a Golgi
area of A = 100 µm2. Assume Golgi proteins diffuse down
the tube with a diffusion constant of 1 µm2/s (Cole et al.,
1996a). To favor diffusion as much as possible assume the
concentration is 1 (arbitrary units per area) on the Golgi
end of the tube and 0 on the ER side, and that the ER is perfectly absorbing and redistribution within it is instantaneous. Then the time to empty the Golgi of its material
would be A × L/ D ×
× d, or 1,000 s. By contrast, a flow
velocity of v = 10 µm/s could accomplish the transfer via
one tube in a time of A/(v
d) = 30 s, irrespective of length
(see Appendix B).
While this velocity is very high in comparison to molecular motors, it is modest on the scale of what surface tension-driven flows can produce. To explain by analogy what may occur within the Golgi-ER system, we can imagine a situation where flow generated in the course of mixing contributes to the mixing process itself. Consider an interface (e.g., oil-water or water-air) with a nonuniform concentration of surfactant. The interfacial tension depends on the surfactant concentration point by point, so it too is nonuniform, and its spatial gradient generates a force per area at the interface. A bulk flow ensues that transports the surfactant. Diffusion still occurs, but it may be overwhelmed by the flow-induced transport.
For the ER-Golgi system, the role of "surfactant" could be played by specific lipids (i.e., cholesterol) from the Golgi interacting with the tails of ER lipids. Alternatively, the Golgi lipid head groups could lower the energy of the ER- cytoplasm or ER-lumen interface, or the Golgi proteins might fulfill either role. Tension differences of order 0.1 to 1 times the thermal energy (kBT) per surfactant would generate velocities of several microns per second (see Appendix B). Membrane flows of this type are either recirculating or must entail an increase in area somewhere since the lipids are incompressible. Thus, we have to imagine that the ER swells to accommodate the Golgi membrane or new ER tubules or cisternae are created. In either case, the mechanical energy generated by the tension difference has to supply the necessary work.
The tension in the ER system, alternatively, could be
due to the action of microtubule motors (i.e., kinesin),
which extend the ER peripherally, while the Golgi membranes are flaccid. The insensitivity of the Golgi blinkout
kinetics to nocodazole and the 10-100-fold lower values of
mechanically induced tension deduced from the kinesin
force compared to plausible chemically induced tensions,
however, lead us to favor a chemical rather than mechanical basis for tension in the ER system. The mechanical tension is f/(4r), where f is the microtubule motor force and
r is the tubule radius (Sheetz and Dai, 1996
).
In conclusion, the similarity in the time of Golgi blinkout when imaging either protein or lipid plus the wavelike
propagation of Golgi material in the ER argue against diffusive transport and suggest flow-based membrane transport
within the ER-Golgi system in BFA-treated cells. Tension-driven membrane flow within biological membranes is a
new concept (Sheetz and Dai, 1996), but if one views
membrane-bound organelles as lipid solvents with dissolved or meshlike protein at different free energy states, then flows might be the norm and not the exception when
different compartments become connected via tubules.
Tubule formation and detachment from organelles would
thus need to be tightly regulated to modulate such velocity-based transport pathways and thereby to maintain organelle integrity. It remains to be elucidated how organelles
generate membrane-associated free energy differences (Do
energy-driven peripheral coat proteins which concentrate
and sort protein and lipid play a role?) and whether such
free energy differences are harnessed by cells to drive organelle disassembly.
Received for publication 6 May 1997 and in revised form 6 October 1997.
1. Abbreviations used in this paper: ARF, ADP-ribosylation factor; BFA, brefeldin A; FRAP, fluorescence recovery after photobleaching; GFP, green fluorescent protein; NEM, N-ethylmaleimide; ROI, region of interest.Diffusion in a Heterogeneous Environment
We want to relate the diffusion constant, Deff, we measured experimentally for spreading of fluorescent protein
through the tubular and cisternal components of the ER to
its ideal value D0, appropriate to a planar bilayer viewed
normally. To do so, we assume the ER is a random mesh
of tubes of average radius r and average length between
connections of L r. Their orientation is random in either
a plane or a volume, and their average density is spacially
nonuniform. The tubes are treated as one-dimensional objects because material introduced at one corner becomes
uniform circumferentially in a time much less than the diffusion time to the next node. We can therefore use D0 to
describe diffusion along an individual tube.
Let there be some mean gradient in the density averaged on scales
L, then Deff is defined by
![]() |
(A1) |
If we assume the ER is isotropic, Deff is a scalar and not a
matrix. For a tube making some angle with respect to
,
the concentration gradient along the tube is reduced to g
cos
and the flux along the tube is D0 g cos
. The projection of that flux along
again (to get the flux needed in
A1 is reduced by another factor of cos
. The average of
cos2
over a sphere (d = 3) is 1/3 or over a circle (d = 2) is
1/2. Hence,
![]() |
(A2) |
To address the problem of inhomogeneity, we assume
the variation in both the thickness of the cell or the volume density of tubes is slow on a scale of L, so we can use
Deff. To determine the flux, , in this inhomogeneous system we let
be the average density of the ER, defined by
the signal a long time after redistribution of fluorescence
from the Golgi and just before photobleach. The flux of
material is no longer proportional to the density gradient
but rather the gradient of the density measured relative
to
, the fractional filling. Thus,
![]() |
(A3) |
The flux is zero when is a fixed fraction of
and when
is uniform, it disappears from A3 and we obtain the conventional equation for flux interms of the density gradient.
The image manipulations after the data was recorded on
disk, and all calculations required for the fitting were done
with programs written in FORTRAN or C expressly for
this purpose. To simulate Eq. A3, the equation was approximated by a discrete difference equation (second order accurate, three point differences in both directions;
Press et al., 1992). The approximate equation conserved the total intensity exactly. The time stepping was done
with the simplest first order accurate explicit scheme. This
did not compromise our results because the experimental
points involved intensity averages over 10 or more pixels
in each direction to reduce instrumental noise and the effects of random movements inside the cell. Our computed
values did not change to two figure accuracy when the time step was decreased by a factor of two or four. To accelerate the time stepping after enough evolution had occured, we would coarsen the mesh.
The reference density was sometimes blurred to eliminate instrumental noise which on the confocal images
could amount to ±10% of the total 8-bit range from pixel
to pixel. The experimental image was sometimes cropped
so as to retain only the cell interest.
The origin of time in the simulations is defined by the image we started from, but the unit is not known until Deff is determined. To fix it, the experimental and numerical data were averaged over identical regions of interest at each time point. The time axis for all the numerical curves was then scaled to optimally match the experiment and Deff read off.
Tension Driven Flow
Little is known about the basic physical-chemical parameters of the Golgi-ER membrane system other than that
the Golgi is adsorbed into the ER rather than the reverse.
Thus, the ER provides a lower (free) energy environment
for the Golgi contents. To estimate the velocities that
could be produced during Golgi redistribution into the
ER, we suppose the free energy difference, or tension if
expressed in energy/area of membrane, is of order lT per
Golgi lipid where
l
1 and T is the thermal energy 4 × 10
14 ergs. It is immaterial precisely which constituents of
the Golgi-ER system are responsible for the tension difference.
Our model for Golgi adsorption is by analogy with a surfactant (Golgi) that modulates the tension of an interface
(the ER). A lateral tension gradient produces a force and
hence a flow. An estimate for the averaged flow velocity
proceeds the same way for any tension-driven flow,
namely the energy per time provided by the tension difference is balanced by the viscous dissipation set up by the
flow. Any back pressure that has to be overcome to add
extra lipid to the ER has to be subtracted from the energy available from the tension.
To model the dissipation, we assume some fraction of
the ER proteins form a rigid matrix through which the lipids and remaining proteins flow. (If instead the ER membranes were entirely mobile would increase because of
the reduced dissipation from whatever larger scale matrix
limits the flow.) The diffusion constant Dp of a protein in
an ideal bilayer is several times 10
9 cm2/s. We can invert
the Einstein relation that relates Dp to the force on an anchored protein when the bilayer flows by at
as
![]() |
(B1) |
Assume there are np proteins/area anchored inside a
tube of length l and diameter d down which the lipids
move with velocity . The energy dissipated per time per
protein is fp
and the total dissipation is
![]() |
(B2) |
The energy per time available from introducing new
material is Pl = lT
nl
d, where nl is the number of lipids/area. Solving Pdiss = Pl for
gives
![]() |
(B3) |
taking l
1, Dp
10
9cm2/s, nl/np
102, L
1µ. The
flow dissipation in a three-dimensional mesh or network
comes predominantly from the region around the inlet
(i.e., the distance to the first branch point), so L was approximated as the spacing between branch points in the ER.
An alternative estimate for Pdiss models the ER as a two
dimensional film flowing through an array of obstacles with
spacing for which D'arcy's law reads (Batchelor, 1967
)
![]() |
(B4) |
where is the tension or energy/area whose gradient
is
the force/area. The constant µ can be evaluated by assuming that the viscous stresses induced by the obstacles is
equivalent to flow in a two-dimensional channel of width
, i.e., µ = 12 vl
l/
2, where vl
1 cm2/s is the kinematic
viscosity of the lipid (Bloom et al., 1991
) and
l the mass/
area of film. The numerical factor comes largely from converting the parabolic velocity profile in the channel v(y)
into
via
The force/area can be converted into a dissipation as in (B2) by multiplying by L and the area/time as in (B2). Thus,
![]() |
(B5) |
![]() |
(B6) |
using
5 nm and other numbers as before.
Our estimates so far merely place an upper bound on
since they assume all the energy in the surface tension difference is available to drive the flow, i.e., there are no dissipative losses other than those attributable to
. In reality,
whatever components are responsible for the tension difference can mix by diffusion and "short out" the potential
responsible for the flow. Given the velocities we are finding, the Golgi material will have to spread quite far into the
ER before intrinsic diffusion becomes competitive with flow.
We thank G. Warren and N. Nakamara (Imperial Cancer Research Fund, UK) for kindly providing antibodies to GM130. We also thank J. Bonifacino, J. Donaldson, K. Hirschberg, J. Ellenberg (NICHID, NIH, Bethesda, MD), and Paul Melancon (University of Alberta, Edmonton, AB) for critical review of the manuscript and Michael Sheetz (Duke University, Chapel Hill, NC) and Josh Zimmerberg (NICHD, NIH, Bethesda, MD) for valuable discussions. We also thank T. Lubensky for an alternative derivation of A2.
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