Previous Article | Next Article 
Infect Immun, August 1998, p. 3727-3735, Vol. 66, No. 8
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Phospholipid Composition of Purified
Chlamydia trachomatis Mimics That of the Eucaryotic
Host Cell
Grant M.
Hatch1 and
Grant
McClarty2 *
Departments of Pharmacology and
Therapeutics1 and
Medical
Microbiology,2 University of Manitoba,
Winnipeg, Manitoba, Canada R3E 0W3
Received 10 March 1998/Returned for modification 30 April
1998/Accepted 29 May 1998
 |
ABSTRACT |
Chlamydia trachomatis is an obligate intracellular
eubacterial parasite capable of infecting a wide range of eucaryotic
host cells. Purified chlamydiae contain several lipids typically found in eucaryotes, and it has been established that eucaryotic lipids are
transported from the host cell to the parasite. In this report, we
examine the phospholipid composition of C. trachomatis
purified from host cells grown under a variety of conditions in which
the cellular phospholipid composition was altered. A mutant CHO cell line, with a thermolabile CDP-choline synthetase, was used to show that
decreased host cell phosphatidylcholine levels had no significant
effect on C. trachomatis growth. However, less
phosphatidylcholine was transported to the parasite and purified
elementary bodies contained decreased levels of phosphatidylcholine.
Brefeldin A, fumonisin B1, and exogenous sphingomyelinase
were used to alter levels of host cell sphingomyelin. None of the
agents had a significant effect on C. trachomatis
replication. Treatment with fumonisin B1 and exogenous
sphingomyelinase resulted in decreased levels of host cell
sphingomyelin. This had no effect on glycerophospholipid trafficking to
chlamydiae; however, sphingomyelin trafficking was reduced and
elementary bodies purified from treated cells had reduced sphingomyelin
content. Exposure to brefeldin A, which had no adverse effect on
chlamydia growth, resulted in an increase in cellular levels of
sphingomyelin and a concomitant increase in the amount of sphingomyelin
in purified chlamydiae. Under the experimental conditions used,
brefeldin A treatment had only a small effect on sphingomyelin
trafficking to the host cell surface or to C. trachomatis.
Thus, the final phospholipid composition of purified C. trachomatis mimics that of the host cell in which it is grown.
| |
INTRODUCTION |
Chlamydiae are obligate
intracellular gram-negative eubacterial parasites that infect a wide
range of eucaryotic host cells and cause a variety of human diseases
(27, 36). Chlamydiae have evolved a complex biphasic life
cycle to facilitate their survival in two discontinuous habitats. The
elementary body (EB) is the metabolically dormant, structurally rigid
extracellular spore-like form that initiates infection by attaching to
a suitable host cell. Following internalization, EBs differentiate into
reticulate bodies (RBs), which are of the metabolically active, fragile
intracellular form that grows within the confines of a vacuole, termed
the chlamydial inclusion, which avoids fusion with cellular lysosomes.
By 16 to 20 h into the infection, while some RBs are still
replicating, others have begun the process of differentiation back into
EBs. Approximately 48 to 72 h after infection, RB replication is
essentially complete, EBs predominate, and the host cell lyses,
releasing EBs to begin a new infection cycle.
Like other gram-negative bacteria, chlamydiae possess a cell envelope
composed of an outer membrane (OM) and inner membrane (IM). The outer
leaflet of the OM contains a unique deep rough lipopolysaccharide which
is synthesized by chlamydiae (4, 5). The inner leaflet of
the OM and both leaflets of the IM are made up of various
phospholipids. In addition to containing lipids typically present in
procaryotes (phosphatidylethanolamine [PE], phosphatidylglycerol
[PG], and phosphatidylserine [PS]), purified chlamydiae contain
lipids more frequently associated with eucaryotes (phosphatidylcholine
[PC], phosphatidylinositol [PI], sphingomyelin [SM], and
cholesterol) (28, 46). The presence of these lipids implies
that eucaryotic lipids are transported to chlamydiae. Recent work by
Hackstadt and colleagues (13-15, 33) with fluorescent 6-[N-(7-nitro-2,1,3-benzoxadiazol-4-yl)amino]hexanoyl
(C6-NBD)-ceramide, which is converted to
C6-NBD-SM by the host cell, clearly established that host
cell SM is transported to chlamydiae. Hackstadt et al. (13-15) proposed that the chlamydial inclusion can best be
described as an aberrant Golgi apparatus-derived vesicle situated
distal to the trans-Golgi apparatus, such that it receives
host-derived lipids from an exocytic pathway. The SM obtained from
Golgi apparatus-derived vesicles fusing with the inclusion are
ultimately sequestered by chlamydiae.
Unlike mammalian cell glycerophospholipids, which contain
straight-chain fatty acids, chlamydial phospholipids possess
branched-chain fatty acids (28, 46). Isoleucine is the
precursor of the 
-keto acid primer needed to initiate branched-chain
fatty acid biosynthesis in prokaryotes (19). We have used
radiolabelled isoleucine to study lipid metabolism in
chlamydia-infected cells (46). Our results indicate that
chlamydiae can synthesize PE, PS, and PG de novo and that host cell
glycerophospholipids are transported to chlamydiae. Host
glycerophospholipids are modified by Chlamydia trachomatis,
such that a host-synthesized straight-chain fatty acid is replaced with
a chlamydia-synthesized branched-chain fatty acid. Although it is
established that chlamydiae obtain phospholipids from the host, it is
not clear whether the host cell regulates which phospholipids are
transported or whether chlamydiae can control which lipids they accept,
thereby regulating their final lipid compositions.
In this study we used a temperature-sensitive mutant Chinese hamster
ovary cell line (CHO 58) with a thermolabile CDP-choline synthetase, as
well as wild-type mouse L929 cells treated with a variety of compounds
that affect cellular phospholipid metabolism, to alter host cell
phospholipid composition. The effects of altered host cell phospholipid
composition on chlamydial growth, phospholipid trafficking, and
metabolism were then determined. Our results indicate that the types of
lipids trafficked are not strictly regulated by the host or chlamydiae
and, as a result, that the final phospholipid compositions of
chlamydiae mimic that of the host cell.
| |
MATERIALS AND METHODS |
Materials.
[2,8-3H]adenine (23 Ci
mmol
1), [methyl-3H]choline (81 Ci mmol1), L-[U-14C]isoleucine
(342 mCi mmol1), [1-14C]palmitic acid (57 mCi mmol1), and [U-14C]serine (150 mCi
mmol1) were obtained from New England Nuclear, Dupont
Canada Inc. Brefeldin A, Bacillus cereus sphingomyelinase,
fumonisin B1, and phospholipid standards were obtained from
Sigma.
C. trachomatis strains and propagation.
C.
trachomatis L2/434/Bu was used throughout this study and was grown
as previously described in monolayers (25) or in suspension culture (12). Unless otherwise indicated, 1 µg of
cycloheximide ml1 was present in the postinfection (p.i.)
growth medium. The various cell lines were infected with C. trachomatis at a multiplicity of infection of 3 to 5 infection-forming units per cell. Mock-infected host cell cultures were
treated in a manner identical to that used with infected cells except
that chlamydiae were not added.
Cell lines and culture conditions.
Wild-type HeLa cells and
mouse L929 cells are routinely maintained in our laboratory and were
cultured in minimal essential medium containing 10% fetal bovine serum
at 37°C (12, 25). The wild-type CHO K1 cells and the
thermolabile CDP-choline synthetase CHO K1 cell line (strain 58)
(10, 11) were provided by D. E. Vance, University of
Alberta, Edmonton, Alberta, Canada. Both the wild-type CHO K1 and the
mutant CHO strain 58 cells were cultured in minimal essential medium
containing 10% fetal bovine serum and 300 µM proline at 33°C, the
permissive temperature, or at 40°C, the nonpermissive temperature for
the CHO 58 cells (10, 11).
Incorporation of radiolabelled adenine into host cell and
C. trachomatis DNA.
C. trachomatis growth was
assessed by measuring the incorporation of radiolabelled adenine into
parasite-specific DNA. Labelling conditions, cell harvesting, and
quantitation of radiolabel incorporated into DNA were conducted as
previously described (25). Radiolabel was added at 22 h
p.i., when C. trachomatis DNA synthesis is at a maximum. All
results were normalized to 106 cells.
Extraction and purification of lipids.
For radiolabelling of
phospholipids, mock-infected or C. trachomatis-infected
cells were incubated with a given radiolabelled precursor (3 µCi/5-cm-diameter dish) beginning at 20 h p.i., the time when
chlamydial phospholipid metabolism is at a maximum (46). Five hours later, the cell layer was washed once with ice-cold phosphate-buffered saline and scraped into 2 ml of methanol-water (1:1
[vol/vol]). For cultures treated with brefeldin A (5 µg
ml1), fumonisin B1 (20 µM), and/or
sphingomyelinase (0.05 U ml1), the compounds were added
at the start of the infection (2 h p.i.) and maintained throughout the
entire growth period unless otherwise indicated. For cultures treated
with brefeldin A, fresh inhibitor was added every 5 h. Procedures
for extraction and purification of lipids were carried out as
previously described (16, 46). Lipids were separated by a
two-dimensional thin-layer-chromatography procedure, which gave good
separation of all the major phospholipids (16, 17). The
organic phase containing the extracted lipids was dried under a stream
of N2 and resuspended in 100 µl of chloroform-methanol (2:1, [vol/vol]). Fifty-microliter aliquots, with appropriate standards, were spotted on 10- by 10-cm-diameter thin-layer Silica Gel
60 plates (Whatman) that had been previously treated with 0.4 M boric
acid. The plates were developed in the first dimension with
chloroform-methanol-water-ammonium hydroxide (70:30:3:2) and in the
second dimension with chloroform-methanol-water (65:35:5). Individual
lipids were visualized with iodine vapor. Areas corresponding to
individual lipids were removed and placed in vials containing Universol
scintillation fluor (ICN Biomedicals, Inc.) for quantitation. The
results were standardized based on the number of milligrams of protein
per dish. Protein was assayed by the method of Lowry et al.
(23), with bovine serum albumin as the standard.
Total phospholipid compositions of mock-infected host cells, C. trachomatis-infected host cells at 40 h p.i., and highly
purified chlamydial EBs were determined as previously described
(16). Highly purified EBs were prepared from suspension
cultures of infected host cells (CHO K1, CHO 58, and mouse L929) at
40 h p.i. For CHO 58 cells, a 1-liter suspension culture was grown
at 33°C until cell density reached 106 ml1.
One-half of the culture was left at 33°C and maintained at a cell
density of 106 ml1. The other half was
shifted to 40°C and left for 60 h. The suspension cultures were
then infected with C. trachomatis (12), and after a further 40 h, the infected cells were harvested. Suspension cultures of other cell types, mock infected or C. trachomatis infected, were grown at 37°C for 40 h. For
mock-infected and C. trachomatis-infected cultures treated
with brefeldin A (5 µg ml1), fumonisin B1
(20 µM), and/or sphingomyelinase (0.05 U ml1) the
inhibitors were added at the start of the infection and maintained in
the culture for the entire 40-h chlamydial growth cycle unless
otherwise indicated. EBs were purified by density gradient
centrifugation (7). The phospholipids were quantitated by
analysis of phospholipid phosphorous (31) after separation on two-dimensional thin-layer-chromatography plates as described above.
The lipids on the developed plate were visualized by spraying with
0.2% orcinol in 2 N sulfuric acid followed by heating at 120°C.
Reaction of cell surface SM with sphingomyelinase.
Delivery
of natural SM to the cell surface was assayed according to the
procedure of Shiao and Vance (34) with the following modifications. All cultures were set up in quadruplicate. Two cultures
each of mock-infected and C. trachomatis-infected cells were
left as untreated controls. Treated cultures had sphingomyelinase (0.05 U ml1) and/or brefeldin A (5 µg ml1)
added to duplicate mock-infected and duplicate C. trachomatis-infected cultures at the start of the chlamydia
infection cycle. Twenty hours later cellular SM was labelled for 5 h with [3H]choline (15 µCi/5-cm-diameter dish),
[14C]serine (3µCi/5-cm-diameter dish), or
[14C]palmitate (3 µCi/5-cm-diameter dish), during which
period transport of the newly synthesized radiolabelled lipids
occurred. At the end of the labelling period, lipids were extracted,
separated by two-dimensional thin-layer chromatography, and counted for radioactivity as described above. The percentage of radiolabelled SM
that is hydrolyzable, 100 × {1 
([3H]SMsphingomyelinase
treated/[3H]SMuntreated
control)}, is used as a measure of natural SM transport to the
cell surface.
| |
RESULTS |
C. trachomatis growth under various experimental
conditions.
A CHO cell line with a mutation in CDP-choline
synthetase (10, 11) and a variety of agents, namely,
brefeldin A, an inhibitor of exocytic vesicular transport from the
Golgi apparatus (21, 22); fumonisin B1, an
inhibitor of SM biosynthesis (26); and sphingomyelinase, an
enzyme that degrades SM, were used throughout this study to alter host
phospholipid metabolism and composition. As an initial experiment, we
assessed the effects of these various agents on C. trachomatis growth and the ability of the mutant CHO cell line to
support chlamydia replication at both the permissive (33°C) and
nonpermissive (40°C) temperatures. As a control for the effect of
temperature alone on C. trachomatis growth, wild-type CHO K1
cells cultured at 33 and 40°C were used as the host. C. trachomatis growth was monitored by measuring the incorporation of
radiolabelled adenine into chlamydia-specific DNA (25).
The results presented in Table
1 indicate
that the mutant CHO 58 cell line was just as good a host for supporting
chlamydial
growth as the wild-type CHO K1 cell line. In both cell
lines,
about 30% more radiolabel was incorporated into chlamydial DNA
at 33°C than at 40°C, suggesting that chlamydial growth was
somewhat
compromised at the higher temperature. Similarly, titration
experiments,
quantitating infectious EB progeny, indicated that there
was no
significant difference between chlamydial replication in
wild-type
CHO K1 cells and that in mutant CHO 58 cells, regardless of
the
incubation temperature. There was about a 20% decrease in the
yield of infectious progeny in both cell lines when incubations
were
carried out at 40°C compared to that at 33°C (data not shown).
At the concentrations used in this study, i.e., 5 µg of brefeldin A
ml
1, 20 µM fumonisin B
1, and 0.05 U of
sphingomyelinase ml
1, none of the agents employed had a
significant effect on
C. trachomatis growth (Table
1). In
all cases the agents were added at the beginning
of the infection (2 h
p.i.) and retained in the medium until growth
was measured by the
addition of radiolabelled adenine at 22 h
p.i.
C. trachomatis growth was also assessed by titration of infectious
progeny, after incubation in the presence of the various agents
for
44 h. There was no significant difference in the numbers of
infectious EBs produced in the absence and presence of the agents
(data
not shown).
Phospholipid trafficking to C. trachomatis grown in
wild-type CHO K1 and mutant CHO 58 cells.
When CDP-choline
synthetase mutant CHO 58 cells are shifted to the nonpermissive
temperature of 40°C, de novo synthesis of PC rapidly ceases and the
level of PC in the cells declines to approximately 50% of control
values (10, 11). To determine the effect of altered host
cell phospholipid composition on C. trachomatis phospholipid
metabolism, we incubated confluent monolayers of CHO 58 cells at 33 or
40°C for 60 h and then infected them with C. trachomatis. At 20 h p.i. [14C]isoleucine was
added, and 5 h later total lipids were extracted from the
cultures. As a control for the effects of temperature alone, an
identical series of cultures was set up with wild-type CHO K1 cells. We
have previously shown that isoleucine is specifically incorporated into
chlamydial branched-chain fatty acids and can serve as a tracer of
phospholipid biosynthesis and trafficking in C. trachomatis-infected cells (46). In contrast,
mock-infected cells incubated with radiolabel showed no incorporation
of isoleucine into phospholipids, verifying that any observed
incorporation into lipids reflects C. trachomatis-specific
activity. Results presented in Fig. 1
show that the patterns of isoleucine incorporation into
glycerophospholipids in C. trachomatis-infected CHO K1 cells are essentially identical at 33 and 40°C. This indicates that temperature alone has little effect on the pattern of de novo chlamydial phospholipid synthesis or trafficking of host-derived lipids
to the organism. In contrast, infected CHO 58 cells show decreased and
increased levels of isoleucine incorporation into PC and PG,
respectively, at 40°C compared to levels at 33°C. This change is
consistent with decreased trafficking of host-derived PC to chlamydiae
and increased de novo synthesis of PG by the parasite at the
nonpermissive temperature.
View larger version (25K):
[in this window]
[in a new window]
|
FIG. 1.
Incorporation of [U-14C]isoleucine into
glycerophospholipids of C. trachomatis-infected wild-type
CHO K1 (A) and thermolabile CDP-choline synthetase CHO strain 58 (B)
cells at 33°C (open bars) and 40°C (hatched bars). The host cells
were held at their respective temperatures for 60 h prior to
infection. The temperature was maintained after infection. Infected
cultures were radiolabelled at 20 h p.i. and harvested 5 h
later. The results for each phospholipid are expressed as percentages
of the total radioactivity incorporated into phospholipids. CL,
cardiolipin. Results are expressed as means ± standard deviations
of results from three separate experiments.
|
|
Decreased trafficking of host PC to chlamydiae should result in a
concomitant decrease in the mass of PC in the organism.
To determine if
this was the case, we used CHO 58 cells grown
in suspension culture as
the host for support of chlamydial growth.
CHO 58 cells were grown at
33°C to a density of 10
6 cells ml
1. The
culture was split in two; one-half was placed at 40°C, and
the other
was kept at 33°C. The cells were held at their respective
temperatures for 60 h, and the density of the 33°C culture was
maintained at 10
6 cells ml
1 during this time.
The cells were then mock infected or infected
with
C. trachomatis and harvested 40 h later. The phospholipid
compositions of mock-infected cells, chlamydia-infected cells,
and
highly purified EBs from cultures at the permissive and nonpermissive
temperatures are shown in Fig.
2. In
agreement with previous reports
(
10), the PC content of the
mock-infected CHO 58 cells decreased
by 42% after incubation at
40°C. Similarly, the PC contents of
C. trachomatis-infected CHO 58 cells and highly purified EBs also
decreased, 44 and 47%, respectively, when the cells and EBs were
incubated at 40°C compared to levels at 33°C. This result is
consistent
with the above-described finding of decreased isoleucine
labelling
of PC in
C. trachomatis-infected CHO 58 cells at
40°C. There were
also changes in PE, PS, and PG content; however,
interpretation
of these results is complicated by the fact that
chlamydiae can
synthesize these three phospholipids (but not PC) de
novo.
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 2.
Phospholipid composition of mock-infected CHO strain 58 cells (A), C. trachomatis-infected CHO strain 58 cells at
40 h p.i. (B), and highly purified EBs prepared from infected CHO
strain 58 cells at 40 h p.i. (C) grown at 33°C (open bars) or
40°C (hatched bars). Phospholipids were quantitated by measuring the
phosphorous associated with a given phospholipid and are expressed as
percentages of the total phospholipid phosphorous. Results are averages
of results from two separate experiments; duplicate results varied by
less than 10%. CL, cardiolipin.
|
|
Effect of fumonisin B1 on phospholipid trafficking to
C. trachomatis.
Fumonisin B1 is structurally
similar to the SM precursor sphinganine and is a competitive inhibitor
of sphinganine N-acyltransferase (26). Treatment
of cultured cells with fumonisin B1 results in a rapid
inhibition of SM biosynthesis, which ultimately leads to a decrease in
SM mass (2, 32, 45). It has also been reported that
fumonisin B1 treatment of cells causes an increase in
serine incorporation into PE (2, 35, 43). We determined the
effects of fumonisin B1 on phospholipid biosynthesis and
trafficking in mock-infected and C. trachomatis-infected
mouse cells. We found that the antibiotic caused no significant change
in the extent of isoleucine incorporation into any of the
glycerophospholipids extracted from treated or untreated C. trachomatis-infected cells (Fig. 3).
View larger version (29K):
[in this window]
[in a new window]
|
FIG. 3.
Incorporation of [14C]isoleucine into
glycerophospholipids of C. trachomatis-infected mouse L
cells in the absence (open bars) and presence (hatched bars) of 20 µM
fumonisin B1. Fumonisin B1 was added at the
start of the infection (2 h p.i.), and radiolabelled isoleucine was
added at 20 h p.i. The cells were harvested 5 h later.
Results are expressed as means ± standard deviations of results
from three separate experiments. CL, cardiolipin.
|
|
Radioactive serine, an SM precursor, was used to directly assess the
effects of fumonisin B
1 on SM synthesis. As reported
previously (
2,
32,
45), we found that fumonisin
B
1 treatment
of mock-infected mouse L cells caused
decreased and increased
incorporation of serine into SM and PE,
respectively (Fig.
4A).
Furthermore,
there was no significant effect on serine incorporation
into PS. Serine
was incorporated into SM to about the same extent
in
C. trachomatis-infected cells as in mock-infected controls.
This
finding is consistent with the fact that chlamydiae are incapable
of de
novo SM synthesis (
37,
46). Fumonisin B
1
treatment of
C. trachomatis-infected mouse cells caused a
similar decrease
in serine labelling of SM and had little or no effect
on PS labelling.
We have previously shown that chlamydiae synthesize PE
from PS
(
46), a reaction catalyzed by PS decarboxylase;
therefore, there
is a large increase in serine labelling of PE in
C. trachomatis-infected
cells compared to the level in
mock-infected controls (Fig.
4B).
In contrast to results with
mock-infected controls, fumonisin
B
1 had little effect on
serine labelling of PE in chlamydia-infected
mouse cells.
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 4.
Incorporation of [14C]serine into
phospholipids of mock-infected mouse L cells (A) and C. trachomatis-infected mouse L cells (B) in the absence (open bars)
and presence (hatched bars) of 20 µM fumonisin B1.
Fumonisin B1 was added at the start of the infection (2 h
p.i.), and radiolabelled serine was added at 20 h p.i. The cells
were harvested 5 h later. Results are expressed as means ± standard deviations of results from three separate experiments.
|
|
To determine if the fumonisin B
1-induced decrease in SM
biosynthesis results in a decrease in SM mass, we examined the
phospholipid
compositions of treated and untreated wild-type mouse
cells,
C. trachomatis-infected mouse cells at 40 h
p.i., and highly purified
EBs. Fumonisin B
1 treatment had
no effect on cardiolipin, PG,
PS, PI, PC, and PE composition in
mock-infected cells,
C. trachomatis-infected
cells, and
purified EBs (data not shown). In contrast, fumonisin
B
1
treatment reduced levels of SM in all cultures by 25 to 30%
(Fig.
5A). This result suggests that decreased
content of host
cell SM results in decreased trafficking of SM to
chlamydiae.
View larger version (26K):
[in this window]
[in a new window]
|
FIG. 5.
SM composition of mock-infected mouse L cells (MI),
C. trachomatis-infected mouse L cells at 40 h p.i.
(L2), and highly purified EBs prepared from infected mouse L cells at
40 h p.i. (EB) grown in the absence (open bars) or presence
(hatched bars) of 20 µM fumonisin B1 (A), 5 µg of
brefeldin A ml1 (B), or 0.05 U of sphingomyelinase
ml1 (C). Phospholipids were quantitated by measuring the
phosphorous associated with a given phospholipid. Results for SM are
expressed as percentages of the total phospholipid phosphorous. Results
are averages of results from two separate experiments; duplicate
results varied by less than 10%.
|
|
Effect of brefeldin A on SM trafficking to C. trachomatis.
While chlamydia growth is not significantly affected
by the presence of brefeldin A (Table 1) (3, 14, 46),
Hackstadt and colleagues (13-15, 33) have shown that a
fluorescent SM analog, C6-NBD-SM synthesized by the host
cell from exogenously added C6-NBD-ceramide, is
transported to chlamydiae via a brefeldin A-sensitive pathway. Using
radiolabelled isoleucine as a tracer for branched-chain fatty acids, we
have previously shown that trafficking of host glycerophospholipids to
chlamydiae occurs by a mechanism that is not affected by brefeldin A
(46). In the above-mentioned studies, it was not determined
if there was a difference in the SM and/or glycerophospholipid
compositions of EBs purified from host cells cultured in the presence
and absence of brefeldin A. The following experiments were carried out
to address this issue.
We first determined the effects of brefeldin A on the incorporation of
radiolabelled serine into SM, PS, and PE in mock-infected
and
C. trachomatis-infected mouse cells. We chose serine as a
precursor
because, in addition to being used by the host cell
for phospholipid
synthesis, it can also be used by chlamydiae
for the synthesis of PS
and PE (
46). In agreement with the results
of numerous
reports (
1,
6,
17,
18,
34), we found that
brefeldin A
stimulated (three- to fourfold) host cell SM biosynthesis
(Fig.
6A). A similar increase in SM
biosynthesis was detected
when radiolabelled choline was used as the
precursor (data not
shown). In addition, levels of serine incorporation
into PS and
PE were decreased and increased, respectively, in
mock-infected
cells treated with brefeldin A (Fig.
6A). Brefeldin A
treatment
of
C. trachomatis-infected mouse cells caused a
similar increase
in serine incorporation into SM (Fig.
6B). In
contrast, the antibiotic
had no significant effect on PS and PE
synthesis. This result
is not surprising, since serine can be directly
used by chlamydiae
for PS and PE, but not SM, biosynthesis. The effects
of brefeldin
A on [
14C]isoleucine incorporation into
glycerophospholipids in
C. trachomatis-infected
mouse cells
was also assessed, and as reported previously (
46),
we found
that there were no significant changes (data not shown).
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 6.
Incorporation of [14C]serine into
phospholipids of mock-infected mouse L cells (A) and C. trachomatis-infected mouse L cells (B) in the absence (open bars)
and presence (hatched bars) of 5 µg of brefeldin A ml1.
Brefeldin A was added at the start of the infection (2 h p.i.), and
radiolabelled serine was added at 20 h p.i. The cells were
harvested 5 h later. Results are expressed as means ± standard deviations of results from three separate experiments.
|
|
To see if the brefeldin A-induced increase in SM synthesis resulted in
an increase in SM mass, we compared the phospholipid
compositions of
untreated and treated mock-infected mouse cells,
C. trachomatis-infected mouse cells at 40 h p.i., and purified
EBs. While there was no change in glycerophospholipid composition
(data
not shown), there was a consistent increase (
40%) in SM
in
brefeldin A-treated samples (Fig.
5B). The magnitudes of the
increases
were similar for mock-infected cells,
C. trachomatis-infected
cells at 40 h p.i., and purified EBs. An
identical set of experiments
was carried out with HeLa cells, instead
of mouse cells, and the
findings were in complete agreement (data not
shown).
Effect of extracellular sphingomyelinase treatment on SM
content.
The majority of cellular SM is located in the exoplasmic
face of a plasma membrane (44). Numerous studies have shown
that treatment of cells in culture with exogenous sphingomyelinase results in a substantial decrease in SM content, and such treatment has
been used to study the transport of SM to the cell surface (18,
29, 34, 39). As a result of their studies with labelled C6-NBD-ceramide in chlamydia-infected cells, Hackstadt and
colleagues (13, 14) concluded that a substantial portion of
the SM endogenously synthesized from the added fluorescent ceramide
analog is transported to the chlamydial inclusion rather than to the
host cell plasma membrane. We determined whether exogenous
sphingomyelinase had any effect on phospholipid metabolism and/or
trafficking in C. trachomatis-infected mouse L cells.
Mouse L cells were infected with
C. trachomatis; one culture
was left as a control, and sphingomyelinase was added to the
other at
the start of the infection. The infected cells were labelled
with
[
14C]isoleucine and harvested 5 h later. No
significant change was
found in the extents of isoleucine
incorporation into any of the
phospholipids, suggesting
that sphingomyelinase treatment caused
no major alteration in
chlamydial growth or glycerophospholipid
metabolism (data not shown). A
similar experiment was conducted
with [
14C]serine as the
phospholipid precursor. Since serine can be used
by both the host and
C. trachomatis for phospholipid synthesis,
an appropriate
mock-infected control was added. As expected with
the mock-infected
controls, exposure to sphingomyelinase resulted
in a decrease in the
amount of radiolabel associated with SM but
had little or no effect on
PS and PE (Fig.
7A). We reasoned that
if
a significant portion of the de novo-synthesized SM in a
C. trachomatis-infected cell was transported to the inclusion
membrane
and chlamydia cell wall (
13,
14), where it would be
protected
from exogenous sphingomyelinase, then there would be an
increase
in the amount of [
14C]serine associated with SM.
The results shown in Fig.
7B indicate
that there was no significant
difference between the amount of
radiolabelled SM protected from
sphingomyelinase degradation in
the
C. trachomatis-infected
cells and that in mock-infected controls.
[
3H]choline and
[
14C]palmitate were also used to label SM, and the
results obtained
were similar to those found with radiolabelled serine
(data not
shown).
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 7.
Incorporation of [14C]serine into
phospholipids of mock-infected mouse L cells (A) and C. trachomatis-infected mouse L cells (B) in the absence (open bars)
and presence (hatched bars) of 0.05 U of sphingomyelinase
ml1. Sphingomyelinase was added at the start of the
infection (2 h p.i.), and radiolabelled serine was added at 20 h
p.i. The cells were harvested 5 h later. Results are expressed as
means ± standard deviations of results from three separate
experiments.
|
|
The effect of exogenous sphingomyelinase treatment on SM mass was
assessed by determining the phospholipid compositions of
mock-infected
cells,
C. trachomatis-infected mouse cells at 40
h
p.i., and purified EBs. The results of the compositional analysis
show
that, while there was little or no change in amounts of
glycerophospholipids
(data not shown), there was consistently less SM
(30 to 40%) in
all three sphingomyelinase-treated samples (Fig.
5C).
Effect of brefeldin A on SM trafficking in C. trachomatis-infected cells.
The percentage of total cellular
SM hydrolyzed by exogenously added sphingomyelinase has been used to
monitor SM and fluorescent C6-NBD-SM transport to the
plasma membrane (18, 34, 39). Conflicting results have been
reported for the effects of brefeldin A on SM transport, ranging from
no effect (34) to essentially complete inhibition
(18). In a final set of experiments, we determined the
effect of brefeldin A on SM trafficking to the plasma membrane in
mock-infected and C. trachomatis-infected mouse L cells.
Three precursors ([14C]serine,
[14C]palmitate, and [3H]choline) were used
to label SM. Similar results were obtained with all three; results for
[3H]choline are shown in Fig.
8. Brefeldin A treatment alone resulted in an increase in [3H]choline incorporation into SM in
both mock-infected and C. trachomatis-infected mouse L cells
(Fig. 8A).
View larger version (34K):
[in this window]
[in a new window]
|
FIG. 8.
(A) Incorporation of [3H]choline into SM
of mock-infected mouse L cells (MI) and C. trachomatis
L2-infected mouse L cells (L2) grown in the absence (open bars) and
presence (hatched bars) of 5 µg of brefeldin A ml1.
[3H]SM synthesis was 18,347 dpm mg1 in
mock-infected control cells and 16,926 dpm mg1 in
L2-infected cells. (B) Transport of natural
[3H]choline-labeled SM to the surfaces of mock-infected
mouse L cells and C. trachomatis L2-infected mouse L cells
grown in the absence (open bars) and presence (hatched bars) of 5 µg
of brefeldin A ml1. Hydrolyzable cell surface SM was
quantitated with an exogenous sphingomyelinase treatment as described
in Materials and Methods. Results are averages of results from two
separate experiments; duplicate results varied by less than 10%.
|
|
The effects of brefeldin A on the transport of natural SM to plasma
membranes, as estimated by susceptibility to hydrolysis
with exogenous
sphingomyelinase, in mock-infected and
C. trachomatis-infected
mouse L cells are shown in Fig.
8B. Under our
experimental conditions,
for both mock-infected control cells and
chlamydia-infected cells,
brefeldin A caused approximately a 20%
decrease in the amount
of cellular SM susceptible to sphingomyelinase
hydrolysis. This
result indicates that the transport of natural SM to
the plasma
membrane is inhibited to some extent by brefeldin A in both
mock-infected
and
C. trachomatis-infected cells. There was
no significant difference
in the percentages of SM hydrolyzed when
mock-infected cultures
were compared to
C. trachomatis-infected cultures. This result
implies that there is
no appreciable sequestration of newly synthesized
SM in
chlamydia-infected cells.
| |
DISCUSSION |
In this study of a CHO cell line with a temperature-sensitive
CDP-choline synthetase, fumonisin B1, brefeldin A, and
sphingomyelinase were used to induce alterations in host cell
phospholipid composition. The effects of these alterations on C. trachomatis growth, phospholipid metabolism, trafficking, and
composition were then determined. In all cases, regardless of how the
alterations in host phospholipid composition were brought about, we
found that C. trachomatis growth and EB progeny infectivity
were not adversely affected. In addition, in every instance the final
phospholipid composition of purified chlamydiae mimicked that of the
host cell in which the parasite was grown. Together, these results
indicate that, at least for the limits within which we could vary host
phospholipid composition, the final lipid composition of chlamydiae did
not appear to be strictly controlled. However, since none of our
treatments resulted in a complete depletion of any host cell
phospholipid, it is not possible to determine, from this study, whether
chlamydiae require host lipids for survival.
Previous studies have established that the phospholipid composition of
purified chlamydiae is a mixture of lipids typically found in
procaryotes and eucaryotes (28, 46). It is known that
C. trachomatis can synthesize two major bacterial
glycerophospholipids, PE and PS, de novo (37, 46). In a
series of studies, Hackstadt and colleagues (13-15) have
shown that fluorescently labelled short-chain SM analogs are
transported from the eucaryotic host to the chlamydial inclusion
membrane and are ultimately incorporated into the parasite. Finally,
Wylie et al. (46) used [14C]isoleucine to
specifically label chlamydial branched-chain fatty acids and showed
that eucaryotic glycerophospholipids were transported to and then
modified by C. trachomatis. Together, these studies clearly
indicate that, at least for phospholipids, there is an intimate
association between chlamydiae and the host cell.
In contrast to PS and PE, C. trachomatis cannot synthesize
PC or SM de novo, and as a result, it is easiest to monitor the effects
of alterations in the compositions of these two host-specific phospholipids on trafficking to chlamydiae. The mutant CHO 58 cell
line, with a thermolabile CDP-choline synthetase, provided an excellent
model system for studying the effects of decreased PC content on PC
trafficking to chlamydiae. Our results indicate that C. trachomatis grows just as well in this cell line as it does in the
wild-type CHO K1 parent at both 33 and 40°C. Trafficking of PC from
the host to chlamydiae was not appreciably affected in wild-type cells
but was greatly reduced in CHO 58 cells at 40°C. The decrease in
trafficking of PC was also reflected by the fact that C. trachomatis EBs, purified from CHO 58 cells cultured at the
nonpermissive temperature, had a substantially decreased PC content.
Three separate approaches were used to alter host cell SM content. A
summary of the effects of the various treatments on the SM contents of
mock-infected cells, C. trachomatis-infected cells, and
highly purified chlamydial EBs is shown in Fig.
9. Fumonisin B1 treatment had
little effect on C. trachomatis replication or isoleucine
labelling of glycerophospholipids, which suggests that phospholipid
trafficking from the host to chlamydiae occurs normally. Similar to
results with mock-infected controls, fumonisin B1 did cause
a significant decrease in SM biosynthesis and mass in C. trachomatis-infected cells. This, in turn, resulted in decreased trafficking of SM and a decline in SM content in highly purified EBs.
View larger version (35K):
[in this window]
[in a new window]
|
FIG. 9.
Summary of the effects of brefeldin A, fumonisin
B1, and sphingomyelinase (SMase) treatment on SM content of
mock-infected mouse L cells (open bars), C. trachomatis-infected mouse L cells at 40 h p.i. (upward
hatched bars), and highly purified EBs prepared from infected mouse L
cells at 40 h p.i. (downward hatched bars).
|
|
We found that treatment of mock-infected or C. trachomatis-infected cells with exogenous sphingomyelinase, which
hydrolyzes only cell surface SM (18, 29, 34, 39), had little
effect on chlamydial growth, glycerophospholipid biosynthesis, or
trafficking. Similar to the findings with uninfected controls,
sphingomyelinase treatment of C. trachomatis-infected cells
resulted in a decrease in radiolabelled serine incorporated into newly
synthesized SM and a decrease in SM mass. Previously, Hackstadt and
colleagues (13, 14, 33) had concluded that C. trachomatis inhabits a unique vesicle which interrupts an exocytic
pathway to intercept host SM in transit from the Golgi apparatus to the
plasma membrane. Quantitative estimates made by microphotometry or
thin-layer chromatography of extracted fluorescent lipids suggested
that up to 40 to 50% of the C6-NBD-SM endogenously
synthesized from C6-NBD-ceramide is retained by
chlamydiae. Given these findings, we anticipated that a significant
portion of the newly synthesized SM in a C. trachomatis-infected cell would be transported to the parasite and
protected from exogenous sphingomyelinase. This should have resulted in
but did not result in an increase in the amount of radiolabelled SM
isolated from sphingomyelinase-treated chlamydia-infected cells
compared to that isolated from mock-infected controls.
Differences in the experimental systems used by Hackstadt et al.
(13, 14, 33) and ourselves may, at least in part, account for this variance. In our study, radiolabelled precursors were used to
follow natural SM trafficking, whereas in the studies of Hackstadt et
al. (13, 14), fluorescent C6-NBD-ceramide and
-SM analogs were used. It is known that the fluorescent short-chain fatty acid renders these analogs more water soluble than their natural
counterparts (30). As a result, these molecules can undergo
spontaneous transfer between donor and acceptor membranes much more
readily.
Brefeldin A was also used as an agent to alter host cell SM content.
While it is clearly established that brefeldin A prevents vesicular
transport of proteins to the cell surface by promoting retrograde
transport of Golgi apparatus components back to the endoplasmic
reticulum (20-22), studies of the effects of the antibiotic on SM transport have been less conclusive. Results varying from essentially complete inhibition (18), partial inhibition
(39, 44), and virtually no inhibition (34) have
been reported. In addition, brefeldin A affects the trafficking of
natural SM and short-chain fatty acid analogs, C6-NBD-SM,
differently. Both van Meer and van't Hof (40) and van
Helvoort et al. (39) found that C6-NBD-SM
transport was not inhibited by brefeldin A whereas natural SM transport
was blocked (39). Clearly, the effects of brefeldin A on SM
trafficking to the cell surface vary depending on the experimental
system used.
Hackstadt et al. (13, 14) used conventional fluorescence and
confocal microscopy to show that brefeldin A blocked transport of
C6-NBD-SM, endogenously synthesized from
C6-NBD-ceramide, to chlamydiae. In addition,
C6-NBD-SM incorporated into the plasma membrane was not
transported to the inclusion to a significant extent (14).
Our results with radiolabelled natural SM indicate that brefeldin A
treatment of both mock-infected cultures and C. trachomatis-infected cells results in an increase in SM
biosynthesis compared to that in the appropriate untreated controls.
Furthermore, transport of newly synthesized SM to the cell surface, as
estimated by susceptibility to exogenous sphingomyelinase, was only
partially inhibited by brefeldin A in both mock-infected and C. trachomatis-infected cells. Finally, brefeldin A treatment
resulted in an increase in the SM content of mock-infected mouse cells,
C. trachomatis-infected mouse cells at 40 h p.i., and
purified EBs. In total, these results suggest that, under our
experimental conditions, brefeldin A has little effect on SM
trafficking to chlamydiae. This finding agrees with our previous
observation that brefeldin A had essentially no effect on
glycerophospholipid trafficking to chlamydiae (46). A
possible explanation for the differences in the findings of Hackstadt
et al. (13, 14) and ourselves, in addition to the different
types of SM tracer used (natural versus short-chain fatty acid analog),
is the length of time C. trachomatis-infected cultures were
exposed to the tracer in the presence of brefeldin A. Hackstadt et al.
(13, 14) treated C. trachomatis-infected cultures
at 18 h p.i. with brefeldin A for 90 min before a short labelling
period (1 h with back exchange) with C6-NBD-ceramide. Fluorescent C6-NBD-SM, endogenously synthesized from
C6-NBD-ceramide, rapidly accumulated in chlamydiae in
untreated cultures but was prevented from trafficking in the presence
of brefeldin A. However, upon longer incubation with
C6-NBD-ceramide, brefeldin A-treated cultures eventually
displayed fluorescent lipid in chlamydia cell walls (14). In
our experiments, we routinely incubated cultures for 5 h with
radiolabelled SM precursors.
The complexity of the system limits the level of our interpretation.
Chlamydial infection alone causes changes in a variety of host cell
processes (15, 24, 27, 36), and the addition of exogenous
agents (brefeldin A, fumonisin B1, and sphingomyelinase) which directly affect host cell lipid metabolism compounds the problem.
All our findings support the central conclusion that the final
phospholipid composition of purified C. trachomatis EBs
mimics that of the host cell. Neither the host nor the parasite appears
to regulate the composition of the lipid mixture transported to or
accepted by chlamydiae. Free-living bacteria, such as Escherichia coli and Bacillus subtilis, are known to tolerate wide
variations in their final phospholipid compositions (8, 9);
therefore, the fact that chlamydiae remain viable with an altered
phospholipid makeup is not unusual.
The trafficking of glycerophospholipids, whether they are fluorescent
short-chain fatty acid analogs (14) or radiolabelled natural
lipids (46), is unaffected by brefeldin A. SM trafficking gives various results, which may be related to the fact that while the
majority of SM is synthesized in the cis-medial Golgi
apparatus (39), some is made in the plasma membrane
(42) and in recycling endosomes (29).
Interestingly, it has recently been shown that the chlamydial vacuole
interacts with the endocytic pathway of the host and shares several
characteristics with recycling endosomes (41). The results
of Hackstadt and colleagues (13-15) indicate that at least
part of the SM transported to chlamydiae comes from fusion of
trans Golgi exocytic vesicles with the inclusion membrane. Previously, we have suggested that C. trachomatis obtains
glycerophospholipids from the host through transient direct membrane
contact with host cell subcellular organelles (46). In this
model the chlamydial vacuole is free to accept lipids from any of the
host subcellular structures (endoplasmic reticulum, Golgi apparatus,
plasma membrane, mitochondria, nucleus, or early endosomes) with which
it may transiently interact as it expands, ultimately occupying a major
portion of the cellular cytoplasm. This explanation accounts for most
of our observations to date regarding phospholipid trafficking in chlamydia-infected cells. In addition, it may also explain why, despite
the fact that many host cell organelles are closely associated with the
chlamydial inclusion, no proteins from any organelle have been found in
the inclusion membrane (14, 33, 38, 41).
| |
ACKNOWLEDGMENTS |
We thank J. L. Wylie, L. L. Wang, and S. G. Cao
for technical assistance.
This work was supported by grants from the Medical Research Council of
Canada to G.M. (GR-13301) and G.M.H. (MT-14261). G.M.H. is a Heart and
Stroke Foundation of Canada scholar.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medical Microbiology, Room 504, Basic Medical Sciences Building,
University of Manitoba, 730 William Ave., Winnipeg, Manitoba, Canada
R3E 0W3. Phone: (204) 789-3307. Fax: (204) 789-3926. E-mail:
mcclart{at}cc.umanitoba.ca.
Editor: V. A. Fischetti
| |
REFERENCES |
| 1.
|
Andrieu, N.,
R. Salvayre, and T. Levade.
1996.
Comparative study of the metabolic pools of sphingomyelin and phosphatidylcholine sensitive to tumor necrosis factor.
Eur. J. Biochem.
236:738-745[Medline].
|
| 2.
|
Badiani, K.,
D. M. Byers,
H. W. Cook, and N. D. Ridgway.
1996.
Effect of fumonisin B1 on phosphatidylethanolamine biosynthesis in Chinese hamster ovary cells.
Biochim. Biophys. Acta
1304:190-196[Medline].
|
| 3.
|
Beatty, P. R., and R. S. Stephens.
1994.
CD+ T-lymphocyte mediated lysis of Chlamydia-infected L cells using an endogenous antigen pathway.
J. Immunol.
153:4588-4595[Abstract].
|
| 4.
|
Belunis, C. J.,
K. E. Mdluli,
C. R. H. Raetz, and F. E. Nano.
1992.
A novel 3-deoxy-D-manno-octulosonic acid transferase from Chlamydia trachomatis required for expression of the genus specific epitope.
J. Biol. Chem.
267:18702-18707[Abstract/Free Full Text].
|
| 5.
|
Brade, H.,
L. Brade, and F. E. Nano.
1987.
Chemical and serological investigations on the genus-specific lipopolysaccharide epitope of Chlamydia.
Proc. Natl. Acad. Sci. USA
84:2508-2512[Abstract/Free Full Text].
|
| 6.
|
Bruning, A.,
A. Karrenbauer,
E. Schnabel, and F. T. Wieland.
1992.
Brefeldin A-induced increase of sphingomyelin synthesis.
J. Biol. Chem.
267:5052-5055[Abstract/Free Full Text].
|
| 7.
|
Caldwell, H. D.,
J. Kromhout, and J. Schachter.
1981.
Purification and partial characterization of the major outer membrane protein of Chlamydia trachomatis.
Infect. Immun.
31:1161-1176[Abstract/Free Full Text].
|
| 8.
|
Cronan, J. E., Jr., and C. O. Rock.
1996.
Biosynthesis of membrane lipids, p. 612-636.
In
F. C. Neidhardt, R. Curtiss III, J. L. Ingraham, E. C. C. Lin, K. B. Low, B. Magasanik, W. S. Reznikoff, M. Riley, M. Schaechter, and H. E. Umbarger (ed.), Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed. ASM Press, Washington, D.C.
|
| 9.
|
de Mendoza, D.,
R. Grau, and J. E. Cronan, Jr.
1993.
Biosynthesis and function of membrane lipids, p. 411-424.
In
A. L. Sonenshein, J. A. Hoch, and R. Losick (ed.), Bacillus subtilis and other gram-positive bacteria. American Society for Microbiology, Washington, D.C.
|
| 10.
|
Esko, J. D., and C. R. H. Raetz.
1980.
Autoradiographic detection of animal cell membrane mutants altered in phosphatidylcholine synthesis.
Proc. Natl. Acad. Sci. USA
77:5192-5196[Abstract/Free Full Text].
|
| 11.
|
Esko, J. D.,
M. M. Wermuth, and C. R. H. Raetz.
1981.
CDP-choline synthetase in an animal cell mutant defective in lecithin formation.
J. Biol. Chem.
256:7388-7393[Free Full Text].
|
| 12.
|
Fan, H.,
R. C. Brunham, and G. McClarty.
1992.
Acquisition and synthesis of folates by obligate intracellular bacteria of the genus Chlamydia.
J. Clin. Invest.
90:1803-1811.
|
| 13.
|
Hackstadt, T.,
M. A. Scidmore, and D. D. Rockey.
1995.
Lipid metabolism in Chlamydia trachomatis-infected cells: directed trafficking of Golgi-derived sphingolipids to the chlamydial inclusion.
Proc. Natl. Acad. Sci. USA
92:4877-4881[Abstract/Free Full Text].
|
| 14.
|
Hackstadt, T.,
D. D. Rockey,
R. A. Heinzen, and M. A. Scidmore.
1996.
Chlamydia trachomatis interrupts an exocytic pathway to acquire endogenously synthesized sphingomyelin in transit from the Golgi apparatus to the plasma membrane.
EMBO J.
15:964-977[Medline].
|
| 15.
|
Hackstadt, T.,
E. R. Fischer,
M. A. Scidmore,
D. D. Rockey, and R. A. Heinzen.
1997.
Origins and functions of the chlamydial inclusion.
Trends Microbiol.
5:288-293[Medline].
|
| 16.
|
Hatch, G. M.
1994.
Cardiolipin biosynthesis in the isolated heart.
Biochem. J.
297:201-208.
|
| 17.
|
Hatch, G. M., and D. E. Vance.
1992.
Stimulation of sphingomyelin biosynthesis by brefeldin A and sphingomyelin breakdown by okadaic acid treatment of rat hepatocytes.
J. Biol. Chem.
267:12443-12451[Abstract/Free Full Text].
|
| 18.
|
Kallen, K.-J.,
P. Quinn, and D. Allan.
1993.
Effects of brefeldin A on sphingomyelin transport and lipid synthesis in BHK21 cells.
Biochem. J.
289:307-312.
|
| 19.
|
Kaneda, T.
1991.
Iso- and anteiso-fatty acids in bacteria: biosynthesis, function, and taxonomic significance.
Microbiol. Rev.
55:288-302[Abstract/Free Full Text].
|
| 20.
|
Klausner, R. D.,
J. G. Donaldson, and J. Lippinscott-Schwartz.
1992.
Brefeldin A: insights into the control of membrane traffic and organelle structure.
J. Cell Biol.
116:1071-1080[Free Full Text].
|
| 21.
|
Lippincott-Schwartz, J.,
L. G. Yuan,
J. S. Bonifacino, and R. D. Klausner.
1989.
Rapid redistribution of Golgi proteins into the ER in cells treated with brefeldin A: evidence for membrane cycling from Golgi to ER.
Cell
56:801-813[Medline].
|
| 22.
|
Lippincott-Schwartz, J.,
J. G. Donaldson,
A. Schweizer,
E. G. Berger,
H.-P. Hauri,
L. G. Yaun, and R. D. Klausner.
1990.
Microtubule-dependent retrograde transport of proteins into the ER in the presence of brefeldin A suggests an ER recycling pathway.
Cell
60:821-836[Medline].
|
| 23.
|
Lowry, O. H.,
N. J. Rosebrough,
A. L. Farr, and R. J. Randall.
1951.
Protein measurement with the Folin phenol reagent.
J. Biol. Chem.
193:265-275[Free Full Text].
|
| 24.
|
McClarty, G.
1994.
Chlamydiae and the biochemistry of intracellular parasitism.
Trends Microbiol.
2:157-164[Medline].
|
| 25.
|
McClarty, G., and G. Tipples.
1991.
In situ studies on incorporation of nucleic acid precursors into Chlamydia trachomatis DNA.
J. Bacteriol.
173:4922-4931[Abstract/Free Full Text].
|
| 26.
|
Merrill, A. H.,
E. Wang,
D. G. Gilchrist, and R. T. Riley.
1993.
Fumonisins and other inhibitors of de novo sphingolipid biosynthesis.
Adv. Lipid Res.
26:215-234[Medline].
|
| 27.
|
Moulder, J. W.
1991.
Interactions of chlamydiae and host cells in vitro.
Microbiol. Rev.
55:143-190[Abstract/Free Full Text].
|
| 28.
|
Newhall, W. J.
1988.
Macromolecular and antigenic composition of chlamydiae, p. 47-70.
In
A. L. Barron (ed.), Microbiology of Chlamydia. CRC Press Inc., Boca Raton, Fla.
|
| 29.
|
Obradors, M. J. M.,
D. Sillence,
S. Howitt, and D. Allan.
1997.
The subcellular sites of sphingomyelin biosynthesis in BHK cells.
Biochim. Biophys. Acta
1359:1-12[Medline].
|
| 30.
|
Rosenwald, A. G., and R. E. Pagano.
1993.
Intracellular transport of ceramide and its metabolites at the Golgi complex: insights from short-chain analogs.
Adv. Lipid Res.
26:101-118[Medline].
|
| 31.
|
Rouser, G. A.,
A. N. Siakotos, and S. Fleischer.
1966.
Quantitative analysis of phospholipids by thin-layer chromatography and phosphorous analysis of spots.
Lipids
1:85-86.
|
| 32.
|
Schroeder, J. J.,
H. M. Crane,
J. Xia,
D. C. Liotta, and A. H. Merrill, Jr.
1994.
Disruption of sphingolipid metabolism and stimulation of DNA synthesis by fumonisin B1. A molecular mechanism for carcinogenesis associated with Fusarium moniliforme.
J. Biol. Chem.
269:3475-3481[Abstract/Free Full Text].
|
| 33.
|
Scidmore, M. A.,
E. R. Fischer, and T. Hackstadt.
1996.
Sphingolipids and glycoproteins are differentially trafficked to the Chlamydia trachomatis inclusion.
J. Cell Biol.
134:363-374[Abstract/Free Full Text].
|
| 34.
|
Shiao, Y.-J., and J. E. Vance.
1993.
Sphingomyelin transport to the cell surface occurs independently of protein secretion in rat hepatocytes.
J. Biol. Chem.
268:26085-26092[Abstract/Free Full Text].
|
| 35.
|
Smith, E. R., and A. H. Merrill, Jr.
1995.
Differential roles of de novo sphingolipid biosynthesis and turnover in the "burst" of free sphingosine and sphinganine, and their 1-phosphates and N-acyl-derivatives, that occur upon changing the medium of cells in culture.
J. Biol. Chem.
270:18749-18758[Abstract/Free Full Text].
|
| 36.
|
Stephens, R. S.
1993.
Challenge of Chlamydia research.
Infect. Agents Dis.
1:279-293.
|
| 37.
|
Stephens, R. S.,
S. Kalman,
C. Fenner, and R. Davis.
1997.
Chlamydia genome project.
http://chlamydia-www.berkeley.edu:4231.
|
| 38.
|
Taraska, T.,
D. M. Ward,
R. S. Ajioka,
P. B. Wyrick,
S. R. Davis-Kaplan,
C. H. Davis, and J. Kaplan.
1996.
The late chlamydial inclusion membrane is not derived from the endocytic pathway and is relatively deficient in host proteins.
Infect. Immun.
64:3713-3727[Abstract].
|
| 39.
|
van Helvoort, A.,
M. L. Giudici,
M. Thielemans, and G. van Meer.
1997.
Transport of sphingomyelin to the cell surface is inhibited by brefeldin A and in mitosis, where C6-NBD-sphingomyelin is translocated across the plasma membrane by a multidrug transporter activity.
J. Cell Sci.
110:75-83[Abstract].
|
| 40.
|
van Meer, G., and W. van't Hof.
1993.
Epithelial sphingolipid sorting is insensitive to the reorganization of the Golgi by nocodazole, but is abolished by monensin in MDCK cells and by brefeldin A in Caco-2 cells.
J. Cell Sci.
104:833-842[Abstract].
|
| 41.
|
van Ooij, C.,
G. Apodaca, and J. Engel.
1997.
Characterization of the Chlamydia trachomatis vacuole and its interaction with the host endocytic pathway in HeLa cells.
Infect. Immun.
65:758-766[Abstract].
|
| 42.
|
Vos, J. P.,
M. L. Giudici,
P. van der Bijl,
P. Magni,
S. Marchesini,
L. M. van Golde, and M. Lopes-Cardozo.
1995.
Sphingomyelin is synthesized at the plasma membrane of oligodendrocytes and by purified myelin membranes: a study with fluorescent- and radiolabelled ceramide analogues.
FEBS Lett.
368:393-396[Medline].
|
| 43.
|
Wang, E.,
W. P. Norred,
C. W. Bacon,
R. T. Riley, and A. H. Merrill, Jr.
1991.
Inhibition of sphingolipid biosynthesis by fumonisins. Implications for diseases associated with Fusarium moniliforme.
J. Biol. Chem.
266:14486-14490[Abstract/Free Full Text].
|
| 44.
|
Warnock, D. E.,
C. Roberts,
M. S. Lutz,
W. A. Blackburn,
W. W. Young, Jr., and J. U. Baenziger.
1993.
Determination of plasma membrane lipid mass and composition in cultured Chinese hamster ovary cells using high gradient magnetic affinity chromatography.
J. Biol. Chem.
268:10145-10153[Abstract/Free Full Text].
|
| 45.
|
Wu, W.-I.,
V. M. McDonough,
J. T. Nickels, Jr.,
J. Ko,
A. S. Fischl,
T. R. Vales,
A. H. Merrill, Jr., and G. M. Carman.
1995.
Regulation of lipid biosynthesis in Saccharomyces cerevisiae by fumonisin B1.
J. Biol. Chem.
270:13171-13178[Abstract/Free Full Text].
|
| 46.
|
Wylie, J. L.,
G. M. Hatch, and G. McClarty.
1997.
Host cell phospholipids are trafficked to and then modified by Chlamydia trachomatis.
J. Bacteriol.
179:7233-7242[Abstract/Free Full Text].
|
Infect Immun, August 1998, p. 3727-3735, Vol. 66, No. 8
0019-9567/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Fukuda, E. Y., Lad, S. P., Mikolon, D. P., Iacobelli-Martinez, M., Li, E.
(2005). Activation of Lipid Metabolism Contributes to Interleukin-8 Production during Chlamydia trachomatis Infection of Cervical Epithelial Cells. Infect. Immun.
73: 4017-4024
[Abstract]
[Full Text]
-
Delevoye, C., Nilges, M., Dautry-Varsat, A., Subtil, A.
(2004). Conservation of the Biochemical Properties of IncA from Chlamydia trachomatis and Chlamydia caviae: OLIGOMERIZATION OF IncA MEDIATES INTERACTION BETWEEN FACING MEMBRANES. J. Biol. Chem.
279: 46896-46906
[Abstract]
[Full Text]
-
Su, H., McClarty, G., Dong, F., Hatch, G. M., Pan, Z. K., Zhong, G.
(2004). Activation of Raf/MEK/ERK/cPLA2 Signaling Pathway Is Essential for Chlamydial Acquisition of Host Glycerophospholipids. J. Biol. Chem.
279: 9409-9416
[Abstract]
[Full Text]
-
Gervassi, A. L., Probst, P., Stamm, W. E., Marrazzo, J., Grabstein, K. H., Alderson, M. R.
(2003). Functional Characterization of Class Ia- and Non-Class Ia-Restricted Chlamydia-Reactive CD8+ T Cell Responses in Humans. J. Immunol.
171: 4278-4286
[Abstract]
[Full Text]
-
Carabeo, R. A., Mead, D. J., Hackstadt, T.
(2003). Golgi-dependent transport of cholesterol to the Chlamydia trachomatis inclusion. Proc. Natl. Acad. Sci. USA
100: 6771-6776
[Abstract]
[Full Text]
-
Fields, K. A., Fischer, E., Hackstadt, T.
(2002). Inhibition of Fusion of Chlamydia trachomatis Inclusions at 32{degrees}C Correlates with Restricted Export of IncA. Infect. Immun.
70: 3816-3823
[Abstract]
[Full Text]
-
Bavoil, P. M., Hsia, R.-c., Ojcius, D. M.
(2000). Closing in on Chlamydia and its intracellular bag of tricks. Microbiology
146: 2723-2731
[Full Text]
-
Stephens, R. S., Kalman, S., Lammel, C., Fan, J., Marathe, R., Aravind, L., Mitchell, W., Olinger, L., Tatusov, R. L., Zhao, Q., Koonin, E. V., Davis, R. W.
(1998). Genome Sequence of an Obligate Intracellular Pathogen of Humans: Chlamydia trachomatis. Science
282: 754-759
[Abstract]
[Full Text]
-
Sweet, C. R., Lin, S., Cotter, R. J., Raetz, C. R. H.
(2001). A Chlamydia trachomatis UDP-N-Acetylglucosamine Acyltransferase Selective for Myristoyl-Acyl Carrier Protein. EXPRESSION IN ESCHERICHIA COLI AND FORMATION OF HYBRID LIPID A SPECIES. J. Biol. Chem.
276: 19565-19574
[Abstract]
[Full Text]
Top
Abstract
Introduction
