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J. Biol. Chem., Vol. 277, Issue 13, 11401-11409, March 29, 2002
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From the Departments of Cell and Molecular Biology, The Scripps
Research Institute, La Jolla, California 92037, the
§ Institute for Childhood and Neglected Diseases, and
Received for publication, October 25, 2001, and in revised form, January 15, 2002
The mechanism(s) of cystic fibrosis transmembrane
conductance regulator (CFTR) trafficking from the endoplasmic reticulum (ER) through the Golgi apparatus, the step impaired in individuals afflicted with the prevalent CFTR- The cystic fibrosis transmembrane conductance regulator
(CFTR)1 is a cAMP-regulated
chloride channel polarized to the apical membrane in numerous epithelia
including those found in lung, pancreas, intestine, and kidney (1, 2).
Although nearly 1000 mutations have been identified in the CFTR gene,
~70% of CF chromosomes contain the To rationally develop therapeutic means to stimulate CFTR- Materials--
The following antibodies were used in this study:
a monoclonal antibody (M3A7) against the second nucleotide-binding
domain of CFTR (15), a monoclonal antibody (p5D4) against the
C-terminal cytoplasmic tail of the vesicular stomatitis virus G protein
(VSV-G) (16), and a polyclonal antibody against Rab6 (B. Goud, Institut Curie, Paris, France) (17). Protein G-Sepharose 4 Fast Flow beads were
from Amersham Biosciences; BFA was from Calbiochem; Complete Protease
Inhibitor Cocktail Tablets were from Roche Molecular Biochemicals;
LipofectAMINE Plus Reagent, Opti-MEM I reduced serum medium, DMEM, and
Vaccinia Virus Infection and Transfection--
BHK, HeLa, and
HEK- 293T cells were maintained in DMEM supplemented with 10% fetal
bovine serum and 100 units/ml each of penicillin and streptomycin in a
5% humidified CO2 incubator at 37 °C. CHO and CHO-15B
cells were maintained Transport Analysis--
Transport analysis of VSV-G was
performed as described previously (18). For transport analysis of CFTR,
medium was removed after 8-10 h of transfection, and cells were washed
two times with phosphate-buffered saline (pre-warmed to 37 °C) and
incubated for 30 min in methionine-deficient minimum Eagle's medium.
Cells were radiolabeled for 20-30 min with 500 µCi of
Trans35S-label and then chased in DMEM containing 10%
fetal calf serum and 10 mM cold methionine. For experiments
utilizing BFA, cells were chased in the above medium containing 5 µg/ml brefeldin A (BFA) or equivalent levels of ethanol as control.
After the indicated chase periods, cells were washed twice with
ice-cold phosphate-buffered saline and lysed for 30 min on ice with
RIPA buffer (50 mM Tris-HCl (pH 7.4), 150 mM
NaCl, 0.1% SDS, 1% deoxycholate, and 1% Triton X-100) supplemented
with a Complete Protease Inhibitor Cocktail Tablet and 1 mM
phenylmethylsulfonyl fluoride. Lysates were spun at 14,000 × g for 10 min at 4 °C to pellet insoluble material, and
supernatants were transferred to fresh tubes and incubated with M3A7
monoclonal antibody (5 µg/ml) overnight at 4 °C with rotation.
Immunoprecipitates were isolated with 50 µl of 50% protein G-Sepharose beads at 4 °C for 3 h. Beads were washed 4 times
with ice-cold RIPA buffer and eluted with 1× Laemmli sample buffer (22) for 1 h at room temperature. Beads were pelleted by brief centrifugation, and supernatants, containing CFTR protein, were separated using 7.5% SDS-PAGE gels. Following electrophoresis, gels
were treated with enhancing solution (125 mM sodium
salicylate, 35% methanol) for 1 h and dried. Signals were
developed by autoradiography and quantitated using a PhosphorImager SI
(Molecular Dynamics, Sunnyvale, CA). Graphical results represent the
mean ± S.E. of at least three independent experiments for all
conditions tested.
CFTR Maturation Is Blocked by Dominant Negative Sar1-GTP--
To
investigate the mechanism(s) of wild-type CFTR trafficking in the early
secretory pathway, we used a recombinant T7-vaccinia virus expression
system (19, 20) to transiently co-express wild-type CFTR and key
components regulating the formation, targeting, and fusion of
endoplasmic reticulum (ER)-derived transport intermediates with Golgi
membranes. This approach has been used previously (23) to examine
transport of CFTR through the secretory pathway, the functional roles
of the coat protein complex II (COPII) and coat protein complex I
(COPI) involved in transport vesicle assembly, and the role of Rab
GTPases and SNAp REceptor (SNARE) proteins involved in membrane fusion in the trafficking of cargo through the
early secretory pathway (18, 23-26).
We first examined the role of the COPII complex, composed of the small
molecular weight GTPase Sar1 and the heterodimeric Sec23-24 and
Sec13-31 complexes in CFTR export from the ER (26-29). To block COPII
vesicle function in BHK cells, we co-expressed wild-type CFTR with
Sar1-GTP(H79G), a constitutively active mutant locked in the GTP-bound
form that inhibits vesicle uncoating leading to the accumulation of ER
to Golgi transport intermediates (28, 30). Co-expression of Sar1 or
other components of the vesicular trafficking pathway with CFTR (see
below) generally leads to a 5-10-fold elevated level of the
component over the endogenous pool, consistent with previous results
(18, 23-26) (data not shown). Following labeling of cells with a pulse
of [35S]methionine, delivery of CFTR to the Golgi was
measured by the conversion of the ~140-150-kDa core-glycosylated
band B pre-Golgi form to ~170-190-kDa complex glycosylated band C
isoform diagnostic of processing by Golgi-associated mannosidases and
glycosyltransferases leading to the addition of polylactosamine (31)
(Fig. 1, A-C).
In control cells, ~30% of CFTR was processed to the mature band C
glycoisoform over 3 h, consistent with the efficiency and rate of
CFTR maturation reported in other stably transfected cell lines (12,
13). By contrast, no detectable levels of CFTR in the band C
glycoisoform were observed following overexpression of Sar1-GTP(H79G)
(Fig. 1B). As a control, under identical conditions we also
tested the effect of Sar1-GTP(H79G) on the processing of the reporter
cargo type 1 transmembrane protein vesicular stomatitis virus
glycoprotein (VSV-G) from the endoglycosidase H (endo H)-sensitive pre-Golgi form to the endo H-resistant, Golgi-processed glycoisoform as
described previously (28, 30). Consistent with previous findings (26,
30, 32-34), transport of VSV-G was potently inhibited by the
Sar1-GTP(H79G) mutant (Fig. 1D). Thus, export of CFTR from the ER, like VSV-G, is dependent on a COPII-mediated mechanism. Consistent with this interpretation, morphological analyses of cells
expressing wild-type CFTR using high resolution deconvolution microscopy showed a significant co-localization of wild-type CFTR with
the Sar1 GTPase (~70% of Sar1 containing punctate structures) and
the Sec23 component of the COPII coat complex (~40% of punctate Sec23 containing structures) (Fig. 1E) that was
significantly reduced in cells expressing the
To quantitatively express the efficiency of maturation of CFTR from
band B to band C glycisoforms, we compared the ratio of CFTR band C to
CFTR band B as a function of time. If the band C/band B (C/B) ratio
remains unaltered relative to the control by co-expression with
dominant negative mutants, CFTR processing to the mature glycoisoform
is not affected. If the C/B ratio is reduced, CFTR processing to the
mature glycoisoform is inhibited. By using this method, we found that
although expression of CFTR alone exhibited a C/B ratio of ~6 after a
3-h chase period, co-transfection with Sar1-GTP(H79G) yielded a C/B
ratio of ~0.1 (Fig. 1C). Interestingly, not only was CFTR
processing blocked by the Sar1-GTP(H79G) mutant but Sar1-GTP(H79G)
stabilized immature CFTR band B and reduced its rate of degradation
~3-6-fold (Fig. 1A).
CFTR Maturation Is Not Blocked by Dominant Negative
Arf1-GTP--
Whereas the above results are consistent with the
generally accepted view that the COPII machinery is involved in the
export of cargo proteins from the ER (26, 29, 32-34, 36), the step following export from the ER generally requires the function(s) of the
coat complex I (COPI) machinery that is recruited to pre-Golgi intermediates consisting of vesicular tubular clusters (VTCs) (14) that
are potentially formed from the fusion of COPII vesicles (37). COPI
components include the small molecular weight GTPase Arf1 and the
coatomer coat complex. The function of the COPI coat complex remains
controversial. COPI may function to regulate anterograde transport of
VTCs from the ER to the Golgi stack, transport within the Golgi stack,
and/or the retrograde transport of recycling components from pre-Golgi
and Golgi membranes to the ER (27, 38, 39).
To investigate the requirement for COPI in the processing of CFTR, we
co-expressed CFTR with Arf1-GTP(Q71L), a dominant negative mutant
locked in the GTP-bound form that inhibits ER to Golgi transport of
VSV-G by blocking COPI coat disassembly (24). Control experiments
demonstrated that the Arf1-GTP(Q71L) mutant was functional under these
conditions as it stimulated coatomer ( CFTR Maturation Is Not Blocked by Dominant Negative Rab1a or
Rab2--
Rab1 and Rab2 are members of the ubiquitous
Rab family of small molecular weight GTPases that are
required for vesicle targeting and fusion in both the exocytic and
endocytic pathways (41, 42). Rab1 regulates both anterograde
trafficking from the ER to the cis-Golgi network and intra-Golgi
transport, whereas Rab2 has been proposed to control retrograde
transport from post-ER, pre-Golgi intermediates to the ER (18,
43-46).
To examine the requirement for Rab1 and Rab2 function in CFTR
maturation, we co-expressed CFTR with Rab1a(N124I) or Rab2(N119I), dominant negative mutants that are defective in guanine nucleotide binding and interfere with ER to Golgi transport in BHK cells (18, 47).
Control experiments demonstrated that the Rab mutants were functionally
expressed and blocked VSV-G processing to the endo H-resistant complex
Golgi glycoisoform as reported previously (18, 47) (Fig.
3D, upper endo Hr
bands). In contrast, neither Rab1(N124I) nor Rab2(N119)
affected CFTR processing from the band B to the band C glycoisoform or the CFTR C/B ratio (Fig. 3, A-C). Thus, dominant negative
Rab GTPases controlling the function of pre-Golgi transport
intermediates required for anterograde or retrograde trafficking
between the ER and Golgi (37, 48, 49) did not interfere with CFTR
maturation.
CFTR Maturation Is Independent of Syn5 Function--
Rab GTPases
control the assembly of the targeting/fusion machinery involved in ER
to Golgi transport (37, 48, 49). This machinery includes members of the
syntaxin family of SNARE proteins (50, 51). Syntaxin 5 (Syn5) is
specifically required for the fusion of COPII transport vesicles with
acceptor Golgi membranes, and overexpression of Syn5 potently inhibits
VSV-G ER to Golgi transport (25, 37, 52).
To examine the role of Syn5 in CFTR processing, we co-expressed CFTR
with full-length Syn5 and followed the kinetics of CFTR maturation in
BHK cells. Similar to dominant negative Arf1 and Rab1a/Rab2 mutants,
overexpression of Syn5 had no effect on CFTR maturation to the band C
glycoisoform (Fig. 4, A-C)
but strongly inhibited the processing of VSV-G (Fig. 4D) in
parallel experiments, confirming that Syn5 was functionally expressed
(25). The lack of effects of dominant negative Arf or Rab components or
overexpression of the Syn5 SNARE component specific for ER to Golgi
transport suggests that CFTR trafficking in the early secretory pathway follows a non-conventional pathway in BHK cells.
Regulation of CFTR Transport by Arf1, Rab1a, and Syn5 Is Cell
Type-specific--
Previous studies (9, 53-55) have demonstrated that
trafficking of CFTR from post-Golgi regulated secretory compartments to
the plasma membrane is cell type-specific. For example, cAMP stimulates
trafficking of vesicles containing CFTR to the cell surface in some
cell types but not others. Therefore, we examined if CFTR transport in
the early secretory pathway was also cell type-specific and universally
insensitive to Arf1, Rab1, and Syn5 function. We overexpressed CFTR
with Sar1-GTP(H79G), Arf1-GTP(Q71L), Rab1(N124I), or Syn5 in a panel of
heterologous cell lines including CHO, HeLa, and 293T cells. In all
cell lines examined, CFTR maturation to the band C glycoisoform was
dependent on Sar1 function (Fig. 5),
indicating that CFTR export from the ER proceeds by a conserved COPII-dependent pathway. Moreover, like the BHK cell line,
we found that CFTR maturation in CHO cells was independent of
Arf1/Rab1a/Syn5 function (Fig. 5A). The inability of Arf1,
Rab1, and Syn5 to inhibit CFTR processing in CHO cells is consistent
with the morphological absence of CFTR from Golgi cisternae in this
cell line (14). In contrast to the above results, CFTR maturation to
the band C glycoisoform in HeLa and 293T cells was dependent on
Arf1/Rab1a/Syn5 function (Fig. 5, B and C), as
the dominant negative GTPase mutants or overexpressed Syn5 strongly
inhibited CFTR maturation. Thus, the mechanism of CFTR transport from
the ER to the Golgi is cell type-dependent.
CFTR Processing Is Dependent on Golgi Function--
Given our
findings that CFTR trafficking in BHK and CHO cells was independent of
Arf1/Rab1/Syn5 function, we next examined if CFTR maturation required a
functional Golgi apparatus. To determine whether CFTR utilizes standard
processing enzymes required for restructuring N-linked
oligosaccharides from mannose-containing glycoisoforms present in the
ER to Golgi-processed glycoisoforms containing galactose and sialic
acid present in the cis, medial, and trans Golgi compartments, we
expressed CFTR in the mutant CHO cell line clone 15B. CHO clone 15B
cells lack the medial Golgi-modifying enzyme GlcNAc transferase I and
therefore cannot modify N-linked oligosaccharides beyond the
Man5 containing cis-Golgi glycoisoform, as has been demonstrated for
VSV-G (56-58). Although CFTR was efficiently processed in parental CHO
cells, CFTR was not processed to the band C glycoisoform in mutant in
CHO-15B cells (Fig. 6A). Thus, CFTR requires a predominantly medial Golgi-localized processing enzyme
GlcNAc transferase I for its maturation.
To determine the extent of contribution of other more trans Golgi
enzymes to the processing of CFTR, we took advantage of BFA, a fungal
metabolite that causes rapid resorption of Golgi cis, medial, and
trans-glycosylation enzymes into the ER but not the trans Golgi network
(TGN) (59). When the cargo protein VSV-G is held in the ER in the
presence of BFA, it partially matures and acquires endo H resistance,
confirming that at least cis and medial Golgi enzymes are redistributed
to the ER (60) (data not shown). By contrast, and consistent with
previous reports (13, 23), CFTR processing from the band B to the band
C glycoisoform in transfected BHK cells was completely blocked by BFA
(Fig. 6B). This result suggests that glycosylation enzymes
located in the distal TGN/endosomal compartments, which are insensitive
to BFA-induced collapse into the ER, may be required for maturation of
CFTR to the band C glycoisoform.
CFTR Maturation Is Partially Dependent on a Rab6 Function--
Two
distinct pathways regulating Golgi to ER retrograde transport have been
described as follows: an early Golgi COPI-dependent and a
late Golgi COPI-independent pathway (39, 61). Given our finding that
CFTR processing was dependent on Golgi function but independent of
COPI/Arf1 function, we considered the possibility that CFTR trafficking
through the secretory pathway was dependent on the recycling of novel
components involved in the late COPI-independent pathway. The
COPI-independent pathway is regulated by the Rab6 GTPase that is
involved in retrograde transport of various Golgi glycosylation enzymes
and movement of bacterial toxins including Shiga toxin/Shiga-like
toxin-1 from the endosome through the TGN to the ER (61-63).
To examine the role of Rab6 in CFTR processing, we co-expressed CFTR
with wild-type and dominant negative Rab6 proteins and followed the
kinetics of CFTR maturation in BHK cells. Overexpression of Rab6
wild-type or Rab6-GDP(T27N), a mutant locked in the inactive GDP-bound
state that prevents retrograde trafficking of Golgi glycosylation
enzymes and toxins but does not affect Golgi structure (61-63), had no
effect on CFTR processing based on the rate of appearance of the band C
glycoisoform (Fig. 7, A-C).
Thus, CFTR processing is not sensitive to the
Rab6-dependent retrograde pathway.
Next, we examined the effects of Rab6-GTP(Q72L), a mutant locked in the
active GTP-bound state. Overexpression of Rab6-GTP(Q72L) triggers
complete collapse of late Golgi compartments (possibly including the
TGN) to the ER and blocks transport to the cell surface (62, 63). If
processing to the band C glycoisoform requires enzymes in a
Rab6-dependent late Golgi compartment, a prediction is that
CFTR retained in the ER under these conditions may become partially
modified. Indeed, although no processing could be detected in the
presence of BFA (Fig. 6B), we observed partial processing of
CFTR to the band C glycoisoform in the presence of the Rab6-GTP(Q72L)
mutant (Fig. 7, A-C). Thus, the complete collapse of Golgi
elements induced by the Rab6 GTP-restricted mutant into the ER suggests
that in addition to early Golgi-associated processing enzymes, late
Golgi and TGN-associated Golgi proteins participate in CFTR processing
in the non-conventional pathway.
CFTR Maturation Is Dependent on Syntaxin 13 Function--
CFTR
processing was dependent on Golgi function in BHK and CHO cells
displaying the non-conventional pathway. Therefore, we considered the
possibility that the non-conventional CFTR trafficking pathway in BHK
cells results in an initial direct delivery of CFTR to the trans Golgi
network/endosomal system (64, 65).
To test the above possibility, we examined the role of several
syntaxins involved in regulating transport at other steps of the
exocytic and endocytic pathways. We initially focused on syntaxin 1 (Syn1) and syntaxin 8 (Syn8). Syn1 is currently recognized to facilitate targeting and fusion of vesicles to the cell surface (50).
Syn1 directly interacts with the CFTR N terminus and inhibits both CFTR
function and cAMP-stimulated CFTR trafficking from post-Golgi organelles to the plasma membrane (66-69). Syn8, by contrast, is preferentially associated with the early endosome (70, 71) and
interacts with the regulatory domain of CFTR, although the functional
significance of this interaction remains unknown (72). Overexpression
of either Syn1 or Syn8 had no measurable effect on CFTR maturation from
the immature band B to the mature band C glycoisoform (data not shown),
suggesting that these SNARE proteins do not modulate CFTR trafficking
in the early secretory pathway.
We next examined the possible involvement of syntaxin 13 (Syn13). Syn13
localizes to both early and late recycling endosomes and regulates
transferrin receptor recycling to a juxta-TGN endosomal compartment
(73-75). Strikingly, overexpression of full-length Syn13 completely
blocked CFTR processing to the mature band C glycoisoform in BHK cells
(Fig. 8, A-C). Moreover,
unlike the block imposed by Sar1-GTP(H79G), overexpression of Syn13 did
not stabilize CFTR band B against degradation (Fig. 8B),
emphasizing the importance of the COPII machinery in these events (Fig.
1). Whereas the CFTR C/B band ratio was ~4 in control cells, the
ratio fell nearly 10-fold to ~0.4 in cells overexpressing Syn13 after a 3-h chase period (Fig. 8C). Syn13 inhibition was
dose-dependent as the general level of expression
correlated with the extent of block of CFTR processing from the band B
to the band C glycoisoform (data not shown). Importantly, Syn13 had no
effect on VSV-G processing to the endo H-resistant Golgi glycoisoform
in parallel experiments (Fig. 8D), indicating that Syn13
inhibition of CFTR processing was specific for the non-conventional
pathway.
Collectively, our data suggest that CFTR maturation through the
non-conventional pathway in BHK cells is achieved via initial trafficking of CFTR through an Arf1/Rab1/Syn5-independent pathway that
may involve the late Golgi/endosomal system, followed by a
Syn13-dependent recycling pathway through the Golgi where
CFTR acquires complex carbohydrates and is processed from the immature band B to the mature band C glycoisoform.
Transport of CFTR through the Early Secretory Can Utilize a
Non-conventional Pathway--
We have described for the first time the
intracellular trafficking of CFTR through the early secretory pathway
at the molecular level. In all cell lines examined, CFTR maturation
from the immature band B to the mature band C glycoisoform was blocked
by co-expression of dominant negative Sar1-GTP(H79G). Thus, CFTR export
from the ER proceeds by an evolutionarily conserved COPII-mediated
pathway. However, following ER export, the mechanism of CFTR maturation was critically dependent on cell type. In BHK and CHO cells, CFTR processing could bypass the requirement for Arf1, Rab1, and Syn5, components necessary for ER to Golgi transport of other cargo proteins
(18, 24, 25, 28, 52). This non-conventional pathway, however, was
sensitive to overexpression of Syn13, a transport component that does
not affect transport of VSV-G through the Golgi via the conventional
pathway. On the other hand, in both HeLa and 293T cells, CFTR
processing to the band C glycoisoform was sensitive to Arf1/Rab1/Syn5.
Given that all cell lines tested house the conventional pathway (as
indicated by the effect of overexpression of dominant negative
transport components on the trafficking of VSV-G), both BHK and CHO
cells must have an uncharacterized post-ER pathway that can be utilized
by CFTR for movement to the Golgi. A limitation of our results is that
we have been unable to transfect efficiently polarized epithelial cell
lines that express CFTR using the vaccinia transient expression.
Because of rapid expression driven by the T7 polymerase, this system
has the advantage of allowing us to monitor effects of lethal dominant negative Sar1, Arf1, and Rab1 mutants (<5 h) prior to more general effects on cell metabolism (26, 43). Conventional transient expression
systems requiring 24-48 h of incubation to obtain sufficient levels of
each mutant to inhibit transport may have secondary effects that would
be difficult to evaluate. However, our results are highly correlative
with previous morphological studies that showed in situ that
in CFTR-expressing polarized cells, CFTR is absent from the Golgi (14),
providing a foundation for the current experiments (see below).
One possibility to explain our results is that during export from the
ER, cargo molecules such as CFTR and VSV-G can be segregated into
distinct classes of COPII carriers with novel destinations (76).
Consistent with this possibly, multiple isoforms of the COPII Sec23/24
selection machinery are found in both yeast and mammalian cells, and
several lines of evidence suggest that they affect selection of
different types of cargo (76-80). Alternatively, following export from
the ER using common COPII machinery components, CFTR is segregated from
the Arf1/Rab1/Syn5 pathway during the maturation of pre-Golgi
intermediates and moves via a more direct pathway to the TGN/endosomal
system. The fact we can detect CFTR maturation via both
Arf1/Rab1/Syn5-dependent and independent pathways indicates
that the inability of Arf1/Rab1/Syn5 mutants to inhibit CFTR transport
in BHK and CHO cells is not simply a consequence of the relatively slow
and inefficient transport properties of wild-type CFTR. Moreover, the
fact that transport of VSV-G in all cell lines tested was inhibited by
Arf1/Rab1/Syn5 suggests that the non-conventional mechanism is utilized
in the presence of the conventional pathway.
The Non-conventional Pathway May Target CFTR to a Late
Golgi/Endosomal Compartment--
The possibility that CFTR is directly
transported from the ER or VTCs to a late Golgi (TGN)/endosomal
compartment via an Arf1-, Rab1-, and Syn5-independent pathway is
consistent with the absence of CFTR from the early and central Golgi
cisternae of the Golgi stack in CHO cells and in epithelial tissues
using morphological approaches (14). A requirement for TGN-localized
processing enzymes came from the observation that although collapse of
the cis, medial, and trans Golgi compartments to the ER by BFA was not
sufficient to support maturation of CFTR, overexpression of Rab6-GTP(Q72L) (which causes collapse of all Golgi compartments, potentially including the TGN) (62) was required to detect partial processing of CFTR from the band B to the band C glycoisoform.
Evidence for a more direct pathway from the ER to the TGN stemmed from
the observation that overexpression of Syn13 potently inhibited CFTR
processing to the band C glycoisoform in BHK cells. In contrast,
overexpression of Syn8 or Syn1, syntaxins that bind CFTR (68, 72), had
no effect on CFTR maturation. The lack of effect of Syn1 is consistent
with the recent report (67) that Syn1 preferentially binds the mature
band C glycoisoform of CFTR in vitro. Thus, Syn1 interaction
with CFTR may occur only following CFTR maturation. This interaction
may be required for CFTR cycling between endosomal and plasma membrane
pools and/or for regulation of surface CFTR function (66-68).
Although the precise function of Syn13 in exocytic or endocytic
trafficking is unknown, one possibility is that Syn13 may physically
interact with CFTR. In preliminary experiments, we have been unable to
demonstrate an interaction between Syn13 and CFTR using conditions
identical to those used to observe the interaction of CFTR with Syn1
(68, 72).2 A second
possibility is that Syn13 may regulate the targeting and fusion of
ER-derived transport intermediates containing CFTR to a late Golgi
(TGN) or endosomal compartment. Alternatively, we cannot exclude the
possibility that Syn13 may control the recycling of a critical
component between the endosomes and the TGN that is required for CFTR
processing from the band B to the band C glycoisoform. Although Syn13
binds EEA1, a Rab5-GTP effector protein involved in early endosome
function (73, 81), we have been unable to demonstrate a dominant
negative effect of Rab5 mutants on CFTR processing to the band C
glycoisoform.2
The potential existence of a direct, non-conventional pathway of CFTR
transport from the ER to terminal Golgi compartments is consistent with
the recent observations (82) of a close apposition between the ER and
the trans-Golgi cisternae by high resolution three-dimensional
tomography. However, the use of such a pathway raises a conundrum.
Processing of N-linked oligosaccharides such as those found
on CFTR occurs through defined, sequential steps by processing enzymes
in the Golgi that are distributed along the cis to trans axis. Thus,
once delivered to the TGN/endosome it would be necessary for CFTR to
recycle back to the cis compartment to initiate processing, a result
inconsistent with morphological analyses (14). Alternatively, given
that the distribution of Golgi processing enzymes occurs as a gradient
(27), it remains possible that processing of CFTR is initiated by low
levels of early processing enzymes present in the TGN. Although it is
unclear why CFTR would utilize such a non-conventional approach to
maturation, one possibility is that the presence of high levels of CFTR
in Golgi compartments could disrupt Golgi function.
Is CFTR Alone in the Use of a Non-conventional
Pathway?--
Alternative trafficking pathways from the ER, which may
initially bypass the Golgi apparatus, have been reported previously (83-91) for cholesterol, plant vacuolar proteinases, the AE1 anion exchanger, and numerous viral proteins. AE1, for example, may be
directly transported from the ER to the plasma membrane where it
initially contains oligosaccharides sensitive to digestion by
endoglycosidase F. Following endocytosis, AE1 recycles to Golgi membranes, where it acquires complex carbohydrates containing N-acetyllactosamine composed of Gal Effects on CFTR Stability--
One unanticipated and important
finding was that overexpression of Sar1-GTP(H79G), which stabilizes
COPII coats on ER-derived export sites and COPII vesicles, stabilized
immature wild-type CFTR band B and decreased degradation by
~3-6-fold. By contrast, overexpression of Sar1-GTP(H79G) did not
stabilize the degradation rate of CFTR-
In contrast to the effects of Sar1 on promoting stability
of wild-type CFTR in the ER, preventing COPI coat disassembly from pre-Golgi intermediates by overexpression of the dominant negative Arf1-GTP(Q71L) mutant had no effect on the maturation or stability of
wild-type or CFTR- Implication for CF Disease--
Our findings on the molecular
mechanism(s) of CFTR trafficking through the early secretory pathway
have important implications for treatment of individuals with CF.
Although the specific trafficking route(s) utilized by CFTR in the
early secretory pathway of polarized epithelial cells in the lung and
other tissues remains unknown, our previous work demonstrating that
CFTR is not readily detectable in Golgi cisternae, but is readily
detected in the ER, plasma membrane, and endosomal compartments of
duodenal crypt and salivary duct cells, suggests that the
non-conventional pathway predominates in epithelia in situ
(14). Because the trafficking of CFTR through the non-conventional
pathway may be restricted to a limited group of proteins, therapeutic
approaches directed toward augmenting this specialized pathway to
promote transport of CFTR- We thank B. Goud for polyclonal Rab6 antibody.
*
This work was supported by an NRSA post-doctoral fellowship
from the National Institutes of Health (to B. D. M.) and National Institutes of Health Grant DK 51870 (to J. R.). This is TSRI
manuscript 14614-CB.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
¶
To whom correspondence should be addressed. Tel.:
858-784-2310; Fax: 858-784-9126; E-mail: webalch@scripps.edu.
Published, JBC Papers in Press, January 17, 2002, DOI 10.1074/jbc.M110263200
2
J.-S. Yoo and W. E. Balch, unpublished observations.
The abbreviations used are:
CFTR, cystic
fibrosis transmembrane conductance regulator;
Arf, ADP-ribosylation
factor;
BFA, brefeldin A;
CF, cystic fibrosis;
COPII, coat protein
complex II;
COPI, coat protein complex I;
ER, endoplasmic reticulum;
VSV-G, vesicular stomatitis virus G protein;
Syn, syntaxin;
endo H, endoglycosidase H;
DMEM, Dulbecco's modified Eagle's medium;
BFA, brefeldin A;
VTCs, vesicular tubular elements;
TGN, trans-Golgi
network;
CHO, Chinese hamster ovary;
SNARE, soluble
N-ethylmaleimide-sensitive factor attachment protein
receptors.
Non-conventional Trafficking of the Cystic Fibrosis
Transmembrane Conductance Regulator through the Early Secretory
Pathway*
, and Mayo Foundation and S. C. Johnson Medical Research
Center, Mayo Clinic, Scottsdale, Arizona 85259
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
F508 mutation leading to cystic fibrosis, is largely unknown. Recent morphological observations suggested that CFTR is largely absent from the Golgi in
situ (Bannykh, S. I., Bannykh, G. I., Fish, K. N.,
Moyer, B. D., Riordan, J. R., and Balch, W. E. (2000)
Traffic 1, 852-870), raising the possibility of a novel
trafficking pathway through the early secretory pathway. We now report
that export of CFTR from the ER is regulated by the conventional coat
protein complex II (COPII) in all cell types tested. Remarkably, in a
cell type-specific manner, processing of CFTR from the
core-glycosylated (band B) ER form to the complex-glycosylated (band C)
isoform followed a non-conventional pathway that was insensitive to
dominant negative Arf1, Rab1a/Rab2 GTPases, or the SNAp
REceptor (SNARE) component syntaxin 5, all of which block the conventional trafficking pathway from the ER to the Golgi. Moreover, CFTR transport through the non-conventional pathway was
potently blocked by overexpression of the late endosomal
target-SNARE syntaxin 13, suggesting that recycling through a
late Golgi/endosomal system was a prerequisite for CFTR maturation. We
conclude that CFTR transport in the early secretory pathway can involve
a novel pathway between the ER and late Golgi/endosomal compartments
that may influence developmental expression of CFTR on the cell surface in polarized epithelial cells.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
F508 mutation, which leads to
severe forms of the genetic disease cystic fibrosis (CF) (3-5).
Deletion of F508 prevents proper folding and trafficking of CFTR from
the endoplasmic reticulum (ER) to the plasma membrane (6, 7). Both
wild-type CFTR and CFTR-F508 can be detected in ER and ER-Golgi transport intermediates, but only wild-type CFTR is readily expressed at the cell surface (2, 8, 9). Both newly synthesized wild-type CFTR
and CFTR-F508 molecules that neither fold productively nor achieve
an ER export-competent conformation are eliminated by covalent addition
of ubiquitin followed by degradation via the proteosome (10, 11).
Whereas ~20-40% of wild-type CFTR nascent chains become properly
folded, are exported from the ER, and acquire complex carbohydrates
characteristic of passage through the Golgi apparatus, negligible
levels of CFTR-F508 follow this pathway, and CFTR-508 is
quantitatively degraded (12, 13).
F508
trafficking from the ER to the cell surface, it is first necessary to
understand the mechanisms and pathways directing wild-type CFTR
trafficking. By using morphological analyses, we recently reported that
although wild-type CFTR was readily detectable in ER membranes,
ER-Golgi transport intermediates, endosomes, and the plasma membrane,
it was largely absent from the Golgi stack in vivo and
in situ (14). However, the molecular mechanism of CFTR
export from the ER as well as the biochemical foundation for its
absence from Golgi cisternae were not addressed. We have therefore
examined the biosynthetic pathway of CFTR trafficking through the early
secretory pathway at the molecular level. We report that not only is
the trafficking pathway by which CFTR acquires complex carbohydrates
cell type-specific but that CFTR maturation can utilize a
non-conventional pathway whereby the protein is first likely to be
transported to distal Golgi compartments and/or the endosomal system
prior to retrieval to earlier Golgi compartments for oligosaccharide
processing to the complex form. Pharmacological modulation of this
non-conventional pathway may be useful to selectively stimulate
CFTR-F508 transport to the plasma membrane.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-minimum Eagle's medium were from Invitrogen; and Easy Tag Express
Protein Labeling 35S-Met Mix was from PerkinElmer Life Sciences.
-minimum Eagle's medium as above. Infection
with T7 RNA polymerase-recombinant vaccinia virus and transfection were
performed as described (18) with minor modifications. Briefly, BHK
cells (1.5 × 106) were plated in 60-mm cell culture
dishes 1 day prior to experimentation. Before infection, cells were
washed twice with Opti-MEM I and then infected with recombinant
vaccinia virus expressing the T7 RNA polymerase (19, 20) at a
multiplicity of 10 plaque-forming units/cell in 1 ml of Opti-MEM I for
30 min with rocking in a 5% humidified CO2 incubator at
37 °C. Infection media were removed; cells were washed twice with
Opti-MEM I, and cells were co-transfected with 7 µg of pcDNA3.1
wild-type CFTR and 7 µg of pcDNA3.1/pET vector (21) containing
trafficking machinery using LipofectAMINE Plus Reagent, following the
manufacturer's instructions. Transfection medium was aspirated after
3 h and replaced with DMEM containing 10% fetal bovine serum for
an additional 5-7 h. Expression of recombinant GTPases and SNARE
components were verified using immunoblotting with specific antibodies
(data not shown) to ensure typical expression levels of 5-10-fold over
endogenous protein levels (21). Experiments comparing effects of
trafficking machinery components on transport of VSV-G and CFTR were
performed in parallel.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (34K):
[in a new window]
Fig. 1.
CFTR processing is blocked by dominant
negative Sar1-GTP. A-C, BHK cells were co-transfected with
pcDNA3.1-CFTR and empty vector (mock) or with
pcDNA3.1-CFTR and pcDNA3.1-GST-Sar1-GTP(H79G), and CFTR
processing was monitored as described under "Experimental
Procedures." Expression levels of transport components were monitored
by immunoblotting with specific antibodies as described under
"Experimental Procedures." A, quantitation of CFTR band
B (% of total B plus C at the 0 time point). Inset,
representative autoradiogram is shown. B, quantitation of
the CFTR band C glycoisoform (% of total B plus C at the 0 time
point). C, ratio of CFTR band C to band B plotted as a
function of time. CFTR maturation from the immature band B to the
mature band C glycoisoform was completely blocked by dominant negative
Sar1-GTP(H79G). D, inhibitory effect of Sar1-GTP(H79G) on
processing of VSV-G from the en- doglycosidase H-sensitive (endo Hs) ER form to the
endo H-resistant (endo Hr) Golgi form in parallel experiments.
E, wild-type and F508 mutant CFTR expressing CHO cell
lines were imaged using high resolution deconvolution microscopy with
the M3A7 anti-CFTR monoclonal antibody (15) followed by Texas
Red-conjugated anti-mouse antibody (r in figure) and with
either Sar1- or Sec23-specific polyclonal antibody followed by
fluorescein isothiocyanate-conjugated anti-rabbit antibodies as
described (14). Arrowheads denote Sar1-containing punctate
structures; arrows indicate punctate regions of overlap of
wild-type CFTR with COPII components that are largely absent in F508
CFTR-expressing cells. Note that ER elements containing CFTR have a
more punctate appearance using deconvolution microscopy as described
previously (14). Insets are 3-4-fold magnifications of
selected regions of images. Quantitation of overlap of CFTR with Sar1
or Sec23 reported under "Results" was performed by counting total
Sar1- or Sec23-containing punctate elements and determining the
fraction in the merged channel that, in addition, contained CFTR.
Bar, 2.5 µm.
F508 mutant that
cannot exit the ER (~15% of Sar1 containing punctate structures;
<10% of Sec23 containing structures) (Fig. 1E) (35).
-COP) recruitment to Golgi
membranes (data not shown) and completely blocked the processing of
VSV-G to the endo H-resistant form (Fig.
2D) as reported previously
(24, 40). Remarkably, overexpression of Arf1-GTP(Q71L) in BHK cells had
no effect on the rate of CFTR band B degradation, the rate of CFTR band
C formation, or the CFTR C/B ratio (Fig. 2, A-C). Thus,
CFTR maturation is Arf1-independent, suggesting that neither the
potential role of Arf1 in anterograde transport nor retrograde
recycling of transport components perturbs egress or degradation of
wild-type CFTR from the ER in BHK cells.
View larger version (18K):
[in a new window]
Fig. 2.
CFTR processing is independent of Arf1
function in BHK cells. A-C, BHK cells were
co-transfected with pcDNA3.1-CFTR and empty vector or with
pcDNA3.1-CFTR and pET-Arf1-GTP(Q71L). A, quantitation of
CFTR band B. Inset, representative autoradiogram is shown.
B, quantitation of the CFTR band C glycoisoform.
C, ratio of CFTR band C to band B plotted as a function of
time. D, inhibitory effect of Arf1-GTP(Q71L) on processing
of VSV-G from the endo H-sensitive (endo Hs) ER form to the
endo H-resistant (endo Hr) Golgi form.
View larger version (18K):
[in a new window]
Fig. 3.
CFTR processing is independent of Rab1a and
Rab2 function in BHK cells. A-C, BHK cells were
cotransfected with pcDNA3.1-CFTR and empty vector or with
pcDNA3.1-CFTR and pET-Rab1a(N124I) or pET-Rab2(N119I).
A, quantitation of CFTR band B. Inset,
representative autoradiogram is shown. B, quantitation of
the CFTR band C glycoisoform. C, ratio of CFTR band C to
band B plotted as a function of time. CFTR processing was not affected
by dominant negative Rab1a(N124I) or Rab2(N119I). D,
inhibitory effects of Rab1a(N124I) and Rab2(N119I) on processing of
VSV-G from the endo H-sensitive (endo Hs) ER form to the endo
H-resistant (endo Hr) Golgi form.
View larger version (16K):
[in a new window]
Fig. 4.
CFTR processing is independent of Syn5
function in BHK cells. A-C, BHK cells were co-transfected
with pcDNA3.1-CFTR and empty vector or with pcDNA3.1-CFTR and
pET-Syn5. A, quantitation of CFTR band B. Inset,
representative autoradiogram is shown. B, quantitation of
the CFTR band C glycoisoform. C, ratio of CFTR band C to
band B plotted as a function of time. CFTR processing was not affected
by Syn5 overexpression. D, inhibitory effect of Syn5 on
processing of VSV-G from the endo H-sensitive (endo Hs) ER form
to the endo H-resistant (endo Hr) Golgi form.
View larger version (21K):
[in a new window]
Fig. 5.
CFTR processing is cell
type-specific. CHO (A), HeLa (B), and HEK
293-T cells (C) were co-transfected with pcDNA3.1-CFTR
and empty vector or with pcDNA3.1-CFTR and
pcDNA3.1-Sar1-GTP(H79G), pET-Arf1-GTP(Q71L), pET-Rab1a(N124I), or
pET-Syn5 as indicated. Whereas Sar1-GTP(H79G) inhibited CFTR maturation
to the band C glycoisoform in all cell lines examined, Arf1-GTP(Q71L),
Rab1a(N124I), and Syn5 inhibited CFTR processing in HeLa and 293T cells
but not CHO cells.
View larger version (25K):
[in a new window]
Fig. 6.
CFTR processing is dependent on Golgi
function. A, wild-type CHO and CHO clone 15B cells
lacking the Golgi enzyme GlcNAc transferase I, were transfected with
pcDNA3.1-CFTR and chased for the indicated periods. CFTR was not
processed to the band C glycoisoform in CHO-15B cells. B,
BHK cells were transfected with pcDNA3.1-CFTR and incubated with or
without 5 µg/ml BFA for the indicated chase periods. BFA completely
blocked CFTR maturation.
View larger version (23K):
[in a new window]
Fig. 7.
CFTR processing is partially dependent on
Rab6 function. A-C, BHK cells were co-transfected with
pcDNA3.1-CFTR and empty vector or with pcDNA3.1-CFTR and the
indicated pET-Rab6 constructs. A, quantitation of CFTR band
B. Upper inset, representative autoradiogram is shown.
Lower inset, immunoblot of Rab6 expression levels.
B, quantitation of the CFTR band C glycoisoform.
C, ratio of CFTR band C to band B plotted as a function of
time. CFTR was only partially processed upon Rab6-GTP(Q72L)
overexpression.
View larger version (17K):
[in a new window]
Fig. 8.
CFTR processing is dependent on Syn13.
A-C, BHK cells were co-transfected with pcDNA3.1-CFTR
and empty vector or with pcDNA3.1-CFTR and pcDNA3.1-Syn13.
A, quantitation of CFTR band B. Inset,
representative autoradiogram is shown. B, quantitation of
the CFTR band C glycoisoform. C, ratio of CFTR band C to
band B plotted as a function of time. D, Syn13
overexpression had no effect on the processing of VSV-G, demonstrating
a specific inhibition of CFTR maturation.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1-4GlcNAc1-3
disaccharides that confer resistance to endoglycosidase F (88).
Interestingly, the mature CFTR band C oligosaccharides also contain
repeating units of N-acetyllactosamine that are distinct
from the conventional complex sugars found on N-linked
oligosaccharides of VSV-G that contain terminal sialic acid residues
(31, 92), again consistent with a non-conventional CFTR trafficking pathway.
F508.2 Combined
with the low level of co-localization of F508 with either Sar1 or
Sec23 in vivo when compared with wild-type CFTR (Fig.
1E), these data suggest that wild-type CFTR, but not
CFTR-F508, may stably interact with components of the COPII export
machinery to divert CFTR away from ER quality control systems that
normally scan the ER for misfolded CFTR (10, 11, 93, 94). We propose that cargo capture by the COPII machinery could represent a key defect
in the difference between export of wild-type and CFTR-F508 from the
ER and are currently exploring the identity of the components found in
CFTR prebudding ER complexes (34) that lead to the export of the
wild-type but not the CFTR-F508 mutant.
F508 in all cells tested.2 Because
Arf1-GTP(Q71L) largely prevents recycling of cargo, particularly molecules containing C-terminal KKXX motifs, from pre-Golgi
intermediates back to the ER (95), the need for retrieval of CFTR
through COPI-dependent intermediates is unlikely to be the
mechanism involved in delivery of CFTR to the degradative machinery.
However, this does not rule out the possibility of a COPI-independent
mechanism involving an uncharacterized retrieval pathway involving
dibasic arginine motifs (96). This is unlikely to involve other
Arf-dependent events as other Arf family members, including
Arf3-GTP(Q71L), Arf4-GTP(Q71L), Arf5-GTP(Q71L), and Arf6-GTP(Q71L),
were also tested and found not to inhibit CFTR processing or
degradation.2
F508 in CF patients may be specific and
not impact the transport of other proteins required for cell
differentiation and growth.
ACKNOWLEDGEMENT
FOOTNOTES
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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