# 2008 The Authors
Journal compilation # 2008 Blackwell Munksgaard
doi: 10.1111/j.1600-0854.2008.00793.xTraffic 2008; 9: 1665–1680Blackwell Munksgaard
Toxoplasma gondii Uses Unusual Sorting Mechanismsto Deliver Transmembrane Proteins into theHost-Cell Vacuole
Claire Gendrin1, Corinne Mercier1,
Laurence Braun1, Karine Musset1,
Jean-Francxois Dubremetz2 and
Marie-France Cesbron-Delauw1,*
1Laboratoire Adaptation et Pathogenie desMicro-organismes, CNRS UMR 5163, Universite JosephFourier GRENOBLE 1, Institut Jean Roget, BP 170,38042 Grenoble cedex 9, France2CNRSUMR5235,Bt24,CC107,UniversitedeMontpellier2,PlaceEugeneBataillon, 34095Montpellier cedex05,France*Corresponding author: Marie-France Cesbron-Delauw,[email protected]
A critical step in infection by the apicomplexan parasite
Toxoplasma gondii is the formation of a membrane-
bound compartment within which the parasite prolifer-
ates. This process relies on a set of secretory organelles
that discharge their contents into the host cell upon
invasion. Among these organelles, the dense granules
are specialized in the export of transmembrane (TM) GRA
proteins, which are major components of the mature
parasitophorous vacuole (PV) membrane. How eukary-
otic pathogens export and sort membrane-bound pro-
teins destined for the host cell is still poorly understood
at the mechanistic level. In this study, we show that
soluble trafficking of the PV-targeted GRA5 TM protein is
parasite specific: when expressed in mammalian cells,
GRA5 is targeted to the plasma membrane and behaves
as an integral membrane protein with a type I toplogy.
We also demonstrate the dual role of the GRA5
N-terminal ectodomain, which is sufficient to prevent
membrane integration within the parasite and is essen-
tial for both sorting and post-secretory membrane inser-
tion into the vacuolar membrane. These results contrast
with the general rule that states that information con-
tained within the cytoplasmic tail and/or the TM domain
of integral membrane proteins dictates their cellular
localization. They also highlight the diversity of sorting
mechanisms that leads to the specialization of secretory
processes uniquely adapted to intracellular parasitism.
Key words: Apicomplexa, dense granules, parasitopho-
rous vacuole, sorting, Toxoplasma gondii, transmem-
brane proteins
Received 9 March 2008, revised and accepted for publica-
tion 3 July 2008, uncorrected manuscript published on-
line 9 July 2008, published online 29 July 2008
Modifications of the host-cell vacuole in which the patho-
gen establishes a safe residence is a strategy commonly
used by the apicomplexan parasites Toxoplasma and
Plasmodium or the bacterial pathogens Legionella and
Chlamydia. Given that some of these modifications involve
parasite-encoded membrane-bound proteins, the patho-
gen has to solve the problem of both their delivery and
membrane targeting beyond its own plasmamembrane. In
contrast to the well-studied prokaryotic secretion systems
(1), how eukaryotic pathogens export and sort membrane-
bound proteins is still poorly understood (2).
Toxoplasma gondii is a widespread obligate intracellular
parasite able to infect almost any nucleated mammalian or
avian cell type. It replicates within a parasitophorous
vacuole (PV) that is isolated from host vesicular traffic.
This vacuole is surrounded by host-cell microtubules,
endoplasmic reticulum (ER) and mitochondria. The PV is
formed upon invasion and originates from both the host-
cell plasma membrane and parasite secretory products. As
any eukaryotic cell, Toxoplasma possesses awell-developed
secretory apparatus that includes a perinuclear ER (3) and
a single-stacked Golgi apparatus (4). Moreover, like other
members of the Apicomplexa phylum, Toxoplasma also
possesses specialized secretory organelles, namely the
micronemes, the rhoptries and the dense granules (DG).
Both entry into the host cell and formation of the PV are
orchestrated by sequential secretion from these three
types of secretory organelles (5). While micronemes and
rhoptries drive early formation of the PV (6), maturation of
the Toxoplasma-replicative vacuole is correlated with the
intravacuolar release of DG proteins, which are targeted
either to the PV-surrounding membrane or to the mem-
branous nanotubular network formed within the vacuolar
space (7,8).
Among the DG proteins, nine proteins, named GRA1 to
GRA9, do not present any homologywith proteins of known
function. Recent data using knock-out parasites support
a role in metabolic exchanges between the parasites and
the host cell (9,10) and in the spatial organization of the
parasites within the PV (11,12). Each GRA protein contains
an N-terminal (Nt) signal peptide (SP), which mediates entry
into the secretory pathway (13). Except for GRA1, which is
a soluble calcium-binding protein (14), all the GRA proteins
identified so far are predicted to contain specific membrane
association domains, which consist of a single typical
a-helical transmembrane (TM) domain in the case of GRA3,
4, 5, 6, 7 and 8 or of amphipathic alpha-helices (GRA2 and 9)
(13). Despite the presence of thesemembrane-association
domains, GRA proteins remain excluded from the parasite
www.traffic.dk 1665
endomembranous system (15). Instead, they form high-
molecular-weight complexes and traffic to the DG in both
a soluble and an aggregated state (8,15–17). They are
secreted into the vacuolar space as soluble complexes (17)
and further associate with distinct PV membranous sub-
compartments: GRA2, 4, 6 and 9 associate with the
intravacuolar membranous nanotubes, while GRA3, 5, 7
and 8 associate with the PV membrane (13).
In eukaryotic cells, TM-domain-bearing proteins with an
ER-type signal sequence at the Nt enter the secretory
pathway and are delivered to the plasma membrane in
absence of any additional signal. In contrast, sorting of
TM-domain-bearing proteins to specific compartments is
mediated by signals present within their cytoplasmic
domain (18), specific residues or motifs present in the
TM domain (19,20) or its length (21). In Toxoplasma, while
it is well established that DG constitute the default
pathway for soluble proteins (22–24), the default route
for TM proteins has not yet been identified. In particular,
sorting of TM proteins to the vacuolar membranes versus
the parasite plasmamembrane remains to be investigated.
GRA5 is the prototypic protein chosen to analyze the
unusual export of parasite-encoded TM proteins to the
host-cell vacuole (15). It is a 21-kDa protein (120 amino
acids, aa) composed of two hydrophobic domains, a SP
and a single a-helical TM domain, the latter being flanked
by the Nt and C-terminal (Ct) hydrophilic domains (25).
Following soluble release into the PV, GRA5 spans the
vacuolar membrane and exposes its Nt to the host-cell
cytosol, while its Ct faces the vacuolar space (15). In this
study, we report that in mammalian cells, GRA5 is targeted
to the plasma membrane with a type I topology, providing
evidence that soluble trafficking of GRA5 in Toxoplasma is
peculiar. To investigate which are the determinants of
GRA5 DG targeting and subsequent PV membrane target-
ing, we substituted each domain of GRA5 with those of
a surface-targeted TM protein (26). We showed that in the
parasite, the Nt ectodomain of GRA5 mediates DG target-
ing and is essential for its selective sorting to the PV
membrane. These results contrast with the broad accep-
tance that targeting signals are present within the Ct tail of
TM proteins.
Results
When expressed in mammalian cells, GRA5 is targeted
to the plasma membrane with a type I topology
To examine if the intracellular soluble trafficking that is
observed for GRA5 in Toxoplasma is evolutionary con-
served, we compared in themammalian human embryonic
kidney (HEK) 293 T-cell line, the behavior of C-terminally
hemagglutinin (HA)-tagged GRA5 (GRA5-H; Figure 1A)
with that of C-terminally HA-tagged CD46 (CD46-H; Fig-
ure 1A) as a TM protein control. CD46 is an ubiquitous
mammalian surface protein, which also contains a single
TM-domain and displays a type I topology at the plasma
membrane (27).
Immunofluorescence microscopy on permeabilized cells
showed that GRA5 is targeted to the plasma membrane,
as indicated by the rim of fluorescence observed at the
cell periphery when using both a mouse serum directed
against the Nt part of GRA5 (anti-GRA5 Nt) (15) and the
anti-HA serum (Figure 1B, left). This staining was very
similar to that observed for CD46-H (Figure 1B, left).
Computational analysis using topology prediction methods
(TMPRED and TMHMM) indicates that GRA5 is expected to
behave as a type I TM protein in mammalian cells, with its
Nt domain extending outside the cell and its Ct domain
within the cytoplasm. To confirm biochemically that GRA5
behaves as an integral membrane protein in mammalian
cells, soluble proteins were separated from membranous
material following mechanical disruption of cells tran-
siently expressing C-terminally HA-FLAG-tagged GRA5
(GRA5-HF), and the partitioning of the protein was ana-
lyzed after treatments of the membranous pellet with
several denaturing agents (Figure 1C). GRA5 was exclu-
sively detected in the high-speed pellet (HSP), which
reflects its membrane association. This association was
not disrupted by treatments capable of releasing peripheral
membrane proteins such as high salt concentration or high
pH. Additionally, GRA5 was not solubilized by 6 M urea but
was totally solubilized by 1% Nonidet P-40 (NP-40), similar
to the CD46 TM protein. As a control, the transiently
expressed mammalian soluble protein was detected ex-
clusively in the high-speed soluble fraction (HSS) of HEK
293 T-cells (MLO2 in Figure 1C). These results demon-
strated that GRA5 behaves as a TM protein when ex-
pressed in a mammalian cell system. Cell surface labeling
was clearly observed when non-permeabilized HEK 293-T
cells expressing GRA5-H were incubated with the anti-
GRA5 Nt serum (Figure 1B, right). In contrast, no signal
was obtained when using the anti-HA antibody, which re-
cognizes the Ct tag (Figure 1B, right). In parallel, immuno-
detection of CD46-H expressed in HEK 293-T cells was
achieved with the TRA2-10 antibody, which recognizes the
Nt domain of CD46 (28), while no staining was observed
with the anti-HA serum (Figure 1B, right). Altogether,
these results showed that the Toxoplasma GRA5 protein
behaves like the TM control CD46 when expressed in HEK
293 T-cells: it is targeted to the plasma membrane with
a type I topology.
In Toxoplasma cells, GRA5 is targeted to the DG,
whereas both CD46 and a TM variant of SAG1 follow
a different route to the parasite surface
To further compare the trafficking of GRA5 with that of
CD46, we stably expressed the latter in Toxoplasma. By
contrast to what was previously observed in mammalian
cells, CD46-HF (Figure 2A) did not colocalize with endog-
enous GRA5 or GRA5-HF in Toxoplasma: in extracellular
parasites of the RH strain stably expressing the protein,
CD46-HF localized predominantly around the nucleus and
1666 Traffic 2008; 9: 1665–1680
Gendrin et al.
was associated to vesicle-like structures throughout the
cytoplasm (Figure 2B, right, lower panel, white arrow-
heads). These vesicles were distinguishable from the DG,
as indicated by the labeling of endogenous GRA5 (Figure
2B, right, lower panel, yellow arrowheads). Overnight in-
fected cells were permeabilized with saponin, which
allows selective permeabilization of both the host cell and
the vacuolar membranes. Under these conditions, no
staining of the parasite surface was observed neither with
the anti-Nt TRA2-10 antibody nor with the anti-Ct anti-HA
serum (Figure 2B, lower panel, left), while in these con-
ditions, the glycosyl-phosphatidylinositol (GPI)-anchored
SAG1 surface antigen was detected (data not shown).
These results suggested that the vesicles containing
CD46-HF were not fusing with the parasite plasma mem-
brane. Interestingly, a TM variant of the surface protein
SAG1, in which the GPI anchor was replaced by the TM and
Ct domains of human CD46 (construct SAG1/CD46TM/
CD46), was described to be targeted to the parasite plasma
membrane (26). A C-terminally HA-FLAG-tagged version of
this construct (SAG1/CD46TM/CD46-HF; Figure 2A) was
stably expressed in Dsag1 parasites. When infected cells
were fully permeabilized by Triton, the staining patterns
obtained with the anti-SAG1 monoclonal antibody (mAb)
and the anti-HA serum were similar, pointing out a surface
labeling as well as a labeling of the nucleus periphery
(Figure 2C, upper right panel). Selective saponin permeabi-
lization of overnight infected cells led to the detection of
the fusion protein at the parasite surface with the anti-
SAG1 mAb only, while no labeling was observed with the
anti-HA serum (Figure 2C, upper left panel). These results
indicated that the protein finally ends up at the parasite
plasma membrane with a type I topology, even if it is
delayed at the level of the parasite ER.
Following permeabilization with Triton-X-100, labeling of
extracellular parasites stably expressing SAG1/CD46TM/
CD46-HF indicated that the fusion is found in intracellular
Figure 1: GRA5 behaves as a type I
TM protein in mammalian cells. A)
Schematic representation of the pro-
teins GRA5-H/HF and CD46-H. The
genes from which the SP, the TM, the
Nt and the Ct domains were amplified
are indicated within the boxes. The
number of aa of each segment is indi-
cated between parentheses, and the
length of the TM domain is provided
below. Stars indicate the HA (H) or HA-
FLAG (HF) tag. B) GRA5-H or CD46-H
transiently expressed in HEK 293-T cells
was detected in cells permeabilizedwith
0.1% Triton-X-100 (permeabilized cells)
or without any prior treatment (living
cells). The Nt domain of each protein
was detected using the TRA-2-10 anti-
CD46mAb and the anti-GRA5 Nt serum,
respectively. The anti-HA rabbit serum
was used to detect the Ct tag. Bars,
10 mm. C) Solubility profile of GRA5-HF
in HEK cells. Transiently transfected
cells were fractionated into a high-speed
membrane pellet (HSP) and a HSS. The
pellet (P) and the soluble fraction (S)
obtained after treatment of the HSP
with several denaturing agents (PBS,
NaCl, CO3, urea and NP-40) were ana-
lyzed by immunoblot. Proteins were
detected using the anti-FLAG mAb
(GRA5-HF and MLO2-F) or the anti-
MCP rabbit serum (endogenous CD46).
MCP, membrane cofactor protein.
MLO2, the human homolog of the
ml02, SP:Q8N806.
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Trafficking to the Toxoplasma Parasitophorous Vacuole
vesicles (Figure 2C, lower panel, white arrowheads) dis-
tinct from the DG (Figure 2C, lower panel, yellow arrow-
heads). Thus, it seems that both CD46-HF and SAG1/
CD46TM/CD46-HF follow a vesicular route that could be
the default pathway for surface-targeted TM proteins. By
contrast, the DG targeting of TM proteins like GRA5
requires expression in Toxoplasma cells and may rely on
intrinsic properties of the GRA proteins.
Figure 2: Legend on next page.
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Gendrin et al.
Targeting of GRA5 to the DG does not depend on its
SP or on its Ct tail
To study whether (a) specific domain(s) of GRA5 would
be responsible for its targeting to the DG, we com-
pared the traffic of endogenous GRA5 with that of the
parasite surface protein SAG1/CD46TM/CD46-HF by sub-
stituting specific domains of GRA5 by those of SAG1 or
CD46.
All the GRA proteins identified up to now present a cleav-
able SP (13), which allows them to enter the secretory
pathway at the ER level. Replacement of the GRA5 SP by
that of CD46 (construct CD46SP/GRA5/GRA5TM/GRA5-HF;
Figure 3A) did not affect the DG targeting of GRA5 in
transiently transfected Dgra5 parasites (Figure 3B). Con-
versely, substitution of the SAG1 SP by that of GRA5 in the
context of the fusion protein SAG1/CD46TM/CD46-HF
(construct GRA5SP/SAG1/CD46TM/CD46-HF; Figure 3A)
and transient expression of this new construct in Dsag1parasites resulted in parasite plasma membrane localiza-
tion with a type I topology (Figure 3C). These results
indicated that the GRA5 SP is neither necessary nor
sufficient to target the protein to the DG.
In higher eukaryotic cells, sorting of TM proteins is often
mediated by signals present within their cytoplasmic tail,
that is the Ct domain in the case of type I TM proteins
(18,29). The potential role of the GRA5 Ct domain was
investigated by stably expressing the fusion protein
GRA5/GRA5TM/CD46-HF (Figure 4A) in Dgra5 parasites.
Immunofluorescence analysis showed that the chimeric
protein colocalized with endogenous GRA3 within the
DG (Figure 4B). Conversely, stable expression of SAG1/
CD46TM/GRA5-HF (Figure 4A) in Dsag1 parasites re-
sulted in the insertion of the fusion in the parasite plasma
membrane with a type I membrane topology (Figure 4C).
Together, these results indicated that the Ct domain of
GRA5 is not involved in the targeting of TM proteins to
the DG.
The Nt domain of GRA5 is sufficient to prevent
membrane insertion within Toxoplasma cells
In a previous study (30), fusion proteins based on the
bacterial alkaline phosphatase (BAP) reporter protein com-
bined with various TM and Ct domains were used to show
that in Toxoplasma, the length of the TM domain is a key
factor that determines targeting to the DG versus the
parasite plasma membrane. We thus examined if specifi-
cities of the GRA5 TM domain are involved in the soluble
targeting of the protein to the DG. Both the fusion proteins
SAG1/CD46TM/CD46-HF (Figure 2A) and SAG1/CD46TM/
GRA5-HF (Figure 4A), which display the 23-aa TM domain
of CD46, were targeted to the parasite surface when
stably expressed in Dsag1 parasites (Figures 2C and 4C).
In contrast, the fusion protein SAG1/GRA5TM/GRA5-HF
(Figure 5A), which contains the 18-aa TM domain of GRA5,
was targeted to the DG when stably expressed in the
same strain (Figure 5C, upper panel). Extracellular para-
sites stably expressing SAG1/CD46TM/GRA5-HF or SAG1/
GRA5TM/GRA5-HF submitted to Triton-X-114 partition pre-
sented the same solubility profile, with both fusion pro-
teins partitioning into both the detergent and the aqueous
phase (Figure 5D). Yet, when parasites were submitted
to cellular fractionation, meaningful differences were
observed (Figure 5D). SAG1/CD46TM/GRA5-HF was exclu-
sively associated with themembranous fractions [HSP and
low-speed pellet (LSP)], and the LSP association was
solubilized by NP-40 only, which reflects a membrane
integration. In contrast, SAG1/GRA5TM/GRA5-HF behaved
as the GRA1 soluble control, being mainly soluble (HSS)
and also present in the LSP, which reflects an aggregated
state characteristic of DG proteins (Figure 5D) (15,16). This
LSP association presented the same characteristics as that
of GRA1 because SAG1/GRA5TM/GRA5-HF was fully sol-
ubilized by both urea and NP-40 (Figure 5D). These results
indicated that the nature of the TM domain is of import-
ance for the soluble targeting to the DG versus the para-
site surface. They were thus in agreement with the data
previously published using the BAP protein (30).
Figure 2: Both CD46-HF and SAG1/CD46TM/CD46-HF traffic through vesicles distinct from the DG, but only SAG1/CD46TM/CD46-
HF reaches the parasite surface. A) Schematic representation of (HA-FLAG tagged) GRA5 and of the fusion proteins CD46-HF and SAG1/
CD46TM/CD46-HF. Stars indicate the HA-FLAG (HF) tag. Annotations and symbols are described in Figure 1. B) Immunolabeling of CD46-
HF compared with that of endogenous GRA5 and GRA5-HF. Endogenous GRA5 was labeled with the anti-GRA5 mAb in intracellular RH
parasites (upper panel). GRA5-HF expressed in the Dgra5 knocked-out strain was labeled with the anti-HA rabbit serum (middle panel).
Upon 0.002% saponin treatment of infected cells, the host-cell membrane and the PVM were selectively permeabilized (host-cell
mbn þ PVmbn perm., left), whereas total permeabilization was obtained by treatment with 0.1% Triton-X-100 (full perm., right). Parasites
stably expressing CD46-HF were labeled as intracellular parasites following saponin permeabilization of infected cells (lower panel, left) or
as extracellular parasites permeabilized with Triton-X-100 (lower panel, right). The TRA-2-10 mAb and the anti-HA rabbit serum were used
to detect the Nt and Ct parts of the fusion protein, respectively. In extracellular parasites, localization of the fusion protein (white
arrowheads) was compared with that of endogenous GRA5 detected with the anti-GRA5 mAb (yellow arrowheads). Bars represent 2 and
5 mm for extracellular and intracellular parasites, respectively. C) Immunostaining of SAG1/CD46TM/CD46-HF in intracellular (upper panel,
bars 5 mm) and extracellular (lower panel, bars 2 mm) Dsag1 parasites stably expressing the fusion protein. In infected cells, the fusion
protein was detected with the anti-SAG1 mAb directed against its Nt domain, while the anti-HA serum was used to detect the Ct tag.
In extracellular parasites permeabilized with Triton-X-100, the anti-HA serum was used to detect the fusion protein (white arrowheads),
while endogenous GRA5 was detected with the anti-GRA5 mAb (yellow arrowheads).
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Trafficking to the Toxoplasma Parasitophorous Vacuole
To determine whether these results were relevant in the
case of GRA5, fusion constructs derived from the GRA5
gene and differing in their TM domain were stably trans-
fected in Dgra5 parasites. Surprisingly, DG targeting was
still observed upon substitution of the GRA5 18-aa TM
domain by the CD46 23-aa TM domain (GRA5/CD46TM/
GRA5) or the CD8 27-aa TM domain (GRA5/CD8TM/GRA5)
(Figure 5A,B,E). Subcellular fractionation analysis of extra-
cellular parasites showed that both the fusion proteins
GRA5/CD46TM/GRA5 and GRA5/CD8TM/GRA5 behaved as
endogenous GRA5 (15): (i) they were mainly associated
with the detergent fraction following Triton extraction and
(ii) they were not only present in the soluble fraction but
also in an aggregated state that was fully solubilized by NP-
40 only (Figure 5F). Taken together, these results showed
that in the context of the SAG1 Nt domain, the properties
of the TM domain influence targeting to the DG versus the
parasite surface. They also showed that the GRA5 Nt
domain contains a very strong signal that prevents TM-
domain-bearing proteins from being inserted into the
parasite plasma membrane and targets them to the DG.
Finally, very importantly, they demonstrated that the signal
contained within the GRA5 Nt domain predominates over
the influence of the TM domain.
Figure 3: The SP domain of GRA5 is neither necessary nor sufficient for DG targeting. A) Schematic representation of endogenous
GRA5 and of the fusion proteins CD46SP/GRA5/GRA5TM/GRA5-HF and GRA5SP/SAG1/CD46TM/CD46-HF. Annotations and symbols are
described in Figure 1. B) Immunostaining of CD46SP/GRA5/GRA5TM/GRA5-HF transiently expressed in Dgra5 parasites (upper panel).
Overnight infected cells permeabilized with Triton-X-100 were incubated with the anti-HA serum and the anti-GRA3 mAb to detect the
chimeric protein and endogenous GRA3, respectively. For a comparison, endogenous GRA5 (detected with the anti-GRA5 mAb) was co-
detected with endogenous GRA3 (detected with the anti-GRA3 serum) in RH parasites (lower panel). Bars, 5 mm. C) Immunolocalization of
the chimeric protein GRA5SP/SAG1/CD46TM/CD46-HF in infected cells permeabilized either with saponin (left) or with Triton-X-100 (right).
The construct was transiently expressed in Dsag1 parasites, which allowed the use of the anti-SAG1 mAb as an anti-Nt antibody. The Ct
part of the fusion protein was detected with the anti-HA serum. Bars, 5 mm.
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Gendrin et al.
The Nt domain is essential for the selective post-
secretory targeting of GRA5 to the PV membrane
Following soluble secretion into the vacuolar space, the
GRA5 TM protein is selectively targeted to the PV mem-
brane (15,25). We (this study) and others (30) have shown
that the TM domain of GRA proteins is of importance in the
soluble targeting to the DG. Whether it is also involved in
post-secretory targeting events was investigated by com-
paring the behavior of the fusion proteins GRA5/CD8TM/
GRA5 and GRA5/CD46TM/GRA5 stably expressed in Dgra5parasites with that of endogenous GRA5. When infected
cells were selectively permeabilized with saponin, the
three proteins detected with the anti-GRA5 mAb colocal-
ized with endogenous GRA3 at the PV membrane (Fig-
ure 6A). This indicated that targeting to the PV membrane
does not rely on peculiar properties of the TM domain.
After removing parasites from overnight infected cells, the
cellular debris and vacuolar materials were fractionated
into a soluble fraction (HSS) and a membranous fraction
(HSP). The fusion proteins partitioned into the HSP frac-
tion, like wild-type GRA5. This association was resistant to
urea, but membrane-associated proteins were solubilized
by NP-40 (Figure 6B). Together, these results showed that
the TM domain of either CD8 or CD46 allows efficient
targeting and membrane insertion of GRA5 into the PV
membrane, indicating that specific properties of the GRA5
TM domain are not involved.
To examine the potential role of the GRA5 Ct domain in
targeting to the PV membrane, the fusion protein GRA5/
GRA5TM/CD46-HFwas stably expressed in Dgra5 parasites,
and its vacuolar localization was compared with that of
endogenous GRA5. Incubation of infected cells permeabi-
lized with saponin with the anti-GRA5mAb showed that the
fusion protein colocalized with GRA3 at the PV membrane,
like endogenous GRA5 (Figure 6A). After selective perme-
abilization of the host-cell plasma membrane with digitonin
(15), the PV was not stained with the anti-HA serum,
whereas under the same condition, a staining of the PV
membrane was observed with the anti-GRA5 mAb directed
against the Nt domain of GRA5 (Figure 6C). These data
confirmed that, similar to the GRA5/GRA5TM/GRA5-HF
fusion protein, GRA5/GRA5TM/CD46-HF is inserted into
the PV membrane, with its Nt protruding into the host-cell
cytoplasm. These data thus demonstrated that the Ct
domain of CD46 does not modify the post-secretory traf-
ficking of GRA5 and thus argue against a role of the GRA5Ct
domain as a targeting determinant to the PV membrane.
Having excluded a role of both the TMand the Ct domains in
the post-secretory membrane targeting of GRA5, we finally
examined the role of the GRA5 Nt domain in these events.
To determine if this domain is sufficient to mediate target-
ing to the PV membrane, the fusion protein GRA5/CD46TM/
CD46-HF (Figure 7A) was stably expressed in Dgra5 para-
sites. Staining of extracellular parasites showed that the
fusion protein was targeted to the DG (Figure S1A). When
infected cells were permeabilized with saponin, a clear
staining of the PV membrane, overlaying that obtained with
the anti-GRA3 mAb (Figure 7B), was observed using the
anti-HA serum. Fractionation analysis performed on over-
night infected cells showed that GRA5/CD46TM/CD46-HF
was associatedwith themembrane fraction (HSP) (Figure 7C).
However, in contrast to GRA5, this association was not
totally released by treatment with NP-40. This may reflect a
stronger interaction with lipids as it can be observed within
raft domains. Together, these results demonstrated that
the Nt domain of GRA5 is sufficient to mediate both
targeting andmembrane insertion of the protein into the PV.
To study the necessity of the GRA5 Nt domain for insertion
into the PV membrane, the chimeric protein SAG1/
Figure 4: The Ct domain of GRA5 is
not involved in the targeting to the
DG. A) Schematic representation of
the fusion proteins GRA5/GRA5TM/
CD46-HF and SAG1/CD46TM/GRA5-
HF. Annotations and symbols are
described in Figure 1. B) Extracellular
parasites of the Dgra5 strain stably
expressing GRA5/GRA5TM/CD46-HF
were permeabilized with Triton-X-
100. The fusion protein and endoge-
nous GRA3 were detected with the
anti-HA rabbit serum and the anti-
GRA3 mAb, respectively. Bars, 2 mm.
C) Immunolocalization of the chimeric
protein SAG1/CD46TM/GRA5-HF in
infected cells permeabilized either
with saponin (left) or with Triton-X-100
(right). The anti-SAG1 mAb was used
as an anti-Nt antibody, while the Ct
part of the fusion protein was detected
with the anti-HA serum. Bars, 5 mm.
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Trafficking to the Toxoplasma Parasitophorous Vacuole
GRA5TM/GRA5-HF (Figure 7A) was stably expressed in
Dsag1 parasites. Unexpectedly, immunofluorescence ana-
lysis of overnight infected cells showed that the protein,
detected with the anti-HA serum, colocalized with GRA1 in
the vacuolar space (Figure 7B). Biochemical analysis of the
vacuolar fraction of infected cells showed that SAG1/
GRA5TM/GRA5-HF, similar to the soluble control protein
GRA1, was present in the PV HSS fraction only (Figure 7D).
The GRA5 Nt domain is thus necessary to mediate the
targeting of a fusion protein to the PV membrane.
The flanking regions of TM domains have been shown to
be of importance in both the targeting and the solubility of
TM proteins (31). The influence of the GRA5 TM domain
Figure 5: Legend on next page.
1672 Traffic 2008; 9: 1665–1680
Gendrin et al.
could thus have been diminished because of the SAG1 Nt
domain environment. To address this possibility, we stably
expressed the construct SAG1/8aa/GRA5TM/GRA5-HF,
which preserved the 8 aa Nt to the GRA5 TM domain
(Figure 7A), in Dsag1 parasites. Following targeting to the
DG (Figure S1B), the fusion protein was detected within
the vacuolar space (Figure 7B) as a fully solubilized protein
(Figure 7D). This indicated that the peculiar properties of
the GRA5 Nt domain do not reside in the Nt boundary of the
TM domain. Taken together, these results demonstrated
that the Nt domain of GRA5 is both necessary and sufficient
tomediate selective targeting to the PVmembrane and that
the membrane association of the protein does not rely on
the Nt juxtamembranous region of the TM domain.
Discussion
During invasion, Toxoplasma secretes numerous proteins
destined to modify host-cell compartments. This process
includes the export of the GRA proteins that are integrated
into the membranes of the vacuole in which the parasite
replicates (PV membrane and intravacuolar nanotubular
network). Such transport of TM proteins outside the
parasite does not involve prior delivery to its own plasma
membrane. Instead, we showed that TM proteins en route
to the parasite surface versus the PV membrane are
segregated throughout the secretory pathway and that
the parasite has evolved specialized sorting systems to
ensure targeting of single-pass TM proteins into PV
membranous subcompartments. Using the TM GRA5
protein as a model, we demonstrated the dual role of its
Nt domain, which prevents membrane insertion in the
parasite early secretory pathway, while it mediates PV
membrane insertion when the protein reaches the con-
fines of the parasite-surrounding vacuole.
Sorting to the DG
T. gondii DG possess two unusual properties: they consti-
tute the default pathway for soluble proteins (22–24) and
part of their luminal content is constituted by single-pass
TM proteins packaged in both a soluble form and aggre-
gates (8,15–17).
We first showed in this study that, when expressed in
mammalian cells, one of these TM proteins, GRA5, dis-
plays biochemical properties similar to those of the integral
membrane protein CD46 and adopts the same type I
topology in the plasma membrane. GRA5 thus possesses
all the elements required for efficient cotranslational inser-
tion into the ERmembrane of mammalian cells. In addition,
because the plasma membrane constitutes the default
compartment for membrane proteins in animal cells, we
concluded that GRA5 does not contain any of the signals
recognized by the mammalian sorting machinery.
By contrast, when expressed in Toxoplasma, both CD46
and a TM variant of the parasite surface antigen SAG1
(SAG1/CD46TM/CD46-HF) behave differently from GRA5:
both fusion proteins localize at the ER and in vesicles
distinct from the DG. Moreover, despite its ER retention,
SAG1/CD46TM/CD46-HF ends up at the parasite surface.
A possible explanation is that the CD46 cytoplasmic
tail contains an ER localization signal that is recognized in
the parasite but not in mammalian cells, as previously
described (31). Alternatively or additionally, the CD46 Ct
domain may carry export signals that are not recognized by
the Toxoplasma machinery. The paucity of N-glycosylation
processes in T. gondii (32) may indeed obviate the lectin-
dependent ER export system that occurs in most eukary-
otic cells. In addition, as shown by urea treatment, GRA5 is
not membrane associated in the DG [(15), this study],
whereas the SAG1/CD46TM/CD46-HF variant behaves as
a TM protein within the parasite. Previous work had shown
that in Toxoplasma, the length of the TM domain is a critical
feature in the segregation of membrane proteins to the DG
versus the Golgi (30). Our results did not contradict these
conclusions as SAG1/GRA5TM/GRA5-HF (TM domain of 18
aa) and SAG1/CD46TM/GRA5-HF (TM domain of 23 aa) are
Figure 5: The Nt domain of GRA5 predominates over the TM domain in the targeting to the DG. A) Schematic representation of the
fusion proteins SAG1/GRA5TM/GRA5-HF, SAG1/CD46TM/GRA5-HF, GRA5/CD46TM/GRA5 and GRA5/CD8TM/GRA5. Annotations and
symbols are described in Figure 1. B) Sequences of the TM domains of GRA5, CD46 and CD8. C) Comparative immunolocalization of
SAG1/GRA5TM/GRA5-HF and SAG1/CD46TM/GRA5-HF stably expressed in Dsag1 parasites. SAG1/GRA5TM/GRA5-HF was detected with the
anti-HA rabbit serum, while endogenous GRA5 was revealed with the anti-GRA5 mAb in extracellular parasites permeabilized with Triton-X-
100 (upper panel, bars 2 mm). After saponin permeabilization of infected cells, the Nt domain of SAG1/CD46TM/GRA5-HF was detected with
the anti-SAG1 mAb, whereas the anti-HA rabbit serum was used to detect the Ct tag (lower panel, bars 5 mm). D) Solubility profile of stably
expressed SAG1/GRA5TM/GRA5-HF and SAG1/CD46TM/GRA5-HF in extracellular parasites. After treatment with Triton-X-114, proteins were
fractionated into an insoluble pellet (I), a detergent phase (D) and an aqueous phase (A). The parasite lysate was also separated by low-speed
centrifugation into cell ghosts (LSP) and a soluble fraction (low-speed supernatant, LSS). This fraction was further separated by a high-speed
spin into a membrane pellet (HSP) and a soluble fraction (HSS). The LSP was submitted to treatments by denaturing agents, and solubilized
proteins (S) were separated from residuals (P) by high-speed centrifugation. The fusion proteins were detected with anti-HA serum. Both
endogenous GRA5 and GRA1, used as controls, were detected using the anti-GRA5mAb and the anti-GRA1mAb, respectively. E) Localization
of GRA5/CD46TM/GRA5 and GRA5/CD8TM/GRA5 stably expressed inDgra5 parasites. Following complete permeabilization with Triton-X-100,
fusion proteinswere detected using the anti-GRA5mAb, and their localizationwas comparedwith that of endogenousGRA3 revealedwith the
anti-GRA3 serum. Bars, 5 mm. F) Cell fractionation analysis of both GRA5/CD46TM/GRA5 and GRA5/CD8TM/GRA5 in extracellular parasites.
Stable transformants were submitted to the cell fractionation procedure described in (D). Fractions were analyzed using the anti-GRA5 mAb,
and the behavior of fusion proteins was compared with that of endogenous GRA5 analyzed in the wild-type RH strain.
Traffic 2008; 9: 1665–1680 1673
Trafficking to the Toxoplasma Parasitophorous Vacuole
targeted to the DG and the parasite surface, respectively.
However, we showed in this study that targeting to the
DG does not solely depend on peculiar properties of the
TM domain because both GRA5/CD8TM/GRA5 (TM domain
of 27 aa) and GRA5/CD46TM/GRA5 (TM domain of 23 aa)
were targeted to the DG pathway. Our results thus
demonstrated that the Nt domain of GRA5 predominates
over the TM domain in DG targeting. Synergy of sorting
signals was previously demonstrated in mammalian cells
to confer robustness to the sorting system [for a review on
sorting of proteins to dense core secretory granules, see
Dikeakos and Reudelhuber (18)]. It is likely that Toxo-
plasma has also developed security systems to ensure
targeting of single-pass TM proteins to the DG using
characteristics of both the TM domain and the Nt domain
as sorting elements.
Biochemical analysis of GRA5/CD8TM/GRA5 (TM domain
of 27 aa) and GRA5/CD46TM/GRA5 (TM domain of 23 aa)
showed that these chimeric proteins behave similarly to
endogenous GRA5 and other TM GRA proteins in being
found as both soluble and aggregated forms, the latter
Figure 6: Neither the TM domain nor
the Ct domain of GRA5 is necessary for
insertion into the PV membrane. A)
Immunolocalization of GRA5/CD46TM/
GRA5, GRA5/CD8TM/GRA5 and GRA5/
GRA5TM/CD46-HF within the PV. HFF cells
were infected either by parasites of the RH
strain or by Dgra5 parasites stably express-
ing the chimeric proteins and selectively
permeabilizedwith saponin. The anti-GRA5
mAb allowed detection of both endoge-
nous GRA5 and fusion proteins. GRA3 co-
staining was obtained with the anti-GRA3
serum. Bars, 5 mm. B) Solubility profile of
vacuolar GRA5/CD46TM/GRA5 and GRA5/
CD8TM/GRA5 compared with that of en-
dogenous GRA5. Cells were infected over-
night by Dgra5 parasites stably expressing
the chimeric proteins. After removal of
intracellular parasites, the membranes
(HSP) were separated from soluble pro-
teins (HSS) by a high-speed spin. The HSP
was treated with denaturing agents, and
membrane pellets (P) were separated from
soluble fractions (S) by a second high-
speed spin. Fractions were analyzed using
the anti-GRA5 mAb. C) Topological study
of GRA5/GRA5TM/CD46-HF in the PV
membrane (upper panel) compared with
that of GRA5-HF (lower panel). Cells were
infected with Dgra5 parasites stably ex-
pressing the chimeric proteins and per-
meabilized with 0.002% digitonin. The
anti-GRA5 mAb and the anti-HA serum
were used as anti-Nt and anti-Ct antibod-
ies, respectively. Bars, 5 mm.
1674 Traffic 2008; 9: 1665–1680
Gendrin et al.
being partially solubilized by urea treatment. We have
recently shown that one prominent feature of TM GRA
proteins is to form large multimeric complexes (>1 MDa)
within the parasite, whereas the other GRA proteins, such
as soluble GRA1, are included into much smaller com-
plexes. It was proposed that formation of such large
complexes would prevent TM insertion of GRA proteins
within the secretory pathway by sequestering their
Figure 7: The Nt domain of GRA5 is both necessary and sufficient to mediate post-secretory membrane insertion into the PV
membrane. A) Schematic representation of the fusion proteins GRA5/CD46TM/CD46-HF, SAG1/GRA5TM/GRA5-HF and SAG1/8aa/
GRA5TM/GRA5-HF. The stripped box represents the 8 aa of GRA5 bordering the GRA5 TM domain. Annotations and symbols are described
in Figure 1. B) Immunolocalization of GRA5/CD46TM/CD46-HF stably expressed in Dgra5 parasites and of the SAG1-derived fusion proteins
SAG1/GRA5TM/GRA5-HF and SAG1/8aa/GRA5TM/GRA5-HF stably expressed in Dsag1 parasites. Infected cells were selectively
permeabilized with saponin. The fusion proteins were detected with the anti-HA serum, and endogenous GRA3 or GRA1 were detected
with the anti-GRA3 or the anti-GRA1 mAb, respectively. Bars, 5 mm. C) Fractionation analysis of vacuolar GRA5/CD46TM/CD46-HF. HFF
cells were infected overnight with a Dgra5 mutant stably expressing the fusion protein and treated as described in Figure 5B. The anti-
GRA5 mAb was used to detect the fusion protein. As a control, endogenous GRA5 was detected with the anti-GRA5 mAb in RH parasites
submitted to the same treatments. D) Analysis of the solubility of vacuolar SAG1/GRA5TM/GRA5-HF and SAG1/8aa/GRA5TM/GRA5-HF.
Both fusion proteins were detectedwith the anti-HA serum, whereas endogenous GRA5 and GRA1were detected with the anti-GRA5 and
anti-GRA1 mAbs, respectively.
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Trafficking to the Toxoplasma Parasitophorous Vacuole
hydrophobic TM domain within the interior of the complex
(17). Our results showed that inclusion into large com-
plexes is likely to depend on the presence of the GRA5 Nt
domain within chimeric TM-bearing proteins. We thus
propose a model in which the Nt domain of TM-domain-
bearing GRA proteins is involved in their incorporation into
multimeric complexes. Consistent with previous work
showing that the DG constitute the default pathway for
soluble proteins (22–24), the formation of such complexes
through mediating aggregation/solubilization would be
sufficient to target the TM-domain-bearing GRA proteins
to the DG (Figure 8). Given that GRA proteins are highly
expressed, they could act as regulators in the conden-
sation process, leading to the formation of dense core
granules. According to this model, the cell specificity of DG
biogenesis would rely on the unique and intrinsic proper-
ties of GRA proteins.
It is not yet clear where proteins destined to the DG are
segregated from proteins destined to the parasite surface
and from the other secreted proteins. In mammalian
secretory cells, sorting of secreted proteins occurs classi-
cally at the trans Golgi network. Considering that the
solubilization process of TM-domain-bearing proteins (i.e.
prevention from stable membrane insertion within the
parasite) is likely to rely in part on the formation of multi-
meric complexes, the simplest model is that oligomeriza-
tion would occur as soon as proteins are synthesized, that
Figure 8: Proposedmodel of both GRA5 soluble export and its post-secretorymembrane insertion into the PVmembrane. GRA5
would enter the ER through a translocon-type apparatus (1). Whether GRA5 inserts temporarily into the ER membrane (2) or whether it is
solubilized at the very moment of its synthesis (20) is not known. GRA5 solubilization would occur through protein–protein interactions,
most probably at the ER level (3). Its Nt domain would allow self-assembly of the protein (GRA5 multimers) or hetero-oligomers formation
through interaction with chaperone proteins such as TgHsp90 or with other TM-domain-bearing GRA proteins (TM GRA oligomers) (3).
Consecutively to their transit through the Golgi complex (4), these high-molecular-weight complexes would aggregate and lead to the
formation of the DG (5). In contrast, surface-targeted TM proteins, such as SAG1-CD46TM-CD46-HF, would follow an alternative route to
the parasite plasmamembrane. Following secretion into the vacuolar space, GRA hetero-oligomerswould dissociate (6) and individual GRA
proteins would interact with specific accessory factors (7 and 70), leading to their proper targeting either to the PV membrane (8) or to the
intravacuolar membranous nanotubular network (80). PPM, parasite plasma membrane; PVM, parasitophorous vacuole membrane; X and
Y, unidentified vacuolar factors. The GRA5 Nt domain is in red. The black rectangles indicate the GRA TM domain, and the pink rectangles
indicate the CD46 TM domain.
1676 Traffic 2008; 9: 1665–1680
Gendrin et al.
is at the ER level (Figure 8). This would fit with the
observation of GRA5 interacting with TgHSP90b (17),
which is likely an ER-resident protein as indicated by the
presence of both a Nt SP and an ER retention sequence
KDEL at its Ct (33). The solubilized/aggregated TM-domain-
bearing GRA proteins would be targeted to the DG by bulk
flow, together with soluble proteins that lack sorting
determinants to other organelles, as was previously sug-
gested (24,34). Whether high-level condensation of GRA
proteins occurs already in the ER or at the trans Golgi
network remains to be investigated.
Targeting to the PV-surrounding membrane
Following soluble secretion from the DG into the PV, GRA5
is targeted to its final destination, the PV delimitating
membrane, where it adopts a TM conformation. Our
results demonstrated that the Nt domain of GRA5 is
necessary and sufficient to mediate membrane insertion
into the PV membrane. Whereas both GRA5/CD46TM/
CD46-HF and GRA5/GRA5TM/GRA5-HF behaved as TM
proteins in the PV membrane, substitution of the Nt
domain of GRA5 by that of SAG1 led to a chimeric protein
(SAG1/GRA5TM/GRA5-HF) that was exclusively soluble
within the vacuolar space. Moreover, given that the Nt
domain of GRA6 was also found to be essential to target
the protein to the membranous nanotubular network
(unpublished data), it is thus likely that the Nt domain of
TM-domain-bearing GRA proteins contains a sorting deter-
minant specific to the different membranous subcompart-
ments of the PV. These results contrast with the broad
acceptance that targeting signals are present within the Ct
tail of TM proteins.
The mechanism by which the Nt domain of GRA5 pro-
motes a conformational change from a soluble stage to
a TM conformation remains to be determined. Interest-
ingly, we have recently shown that the soluble stage of
GRA proteins observed within the parasite and the PV is
correlated with the formation of high-molecular-weight
complexes in which several TM-domain-bearing GRA
proteins associate intimately and that these interactions
are not preserved following insertion into the PV mem-
branes [(17); Ruffiot, AB, JG, K. M., AD,M-F. C-D. and C. M.,
UMR5163, Grenoble, unpublished data]. A modification in
the GRA proteins conformation leading to exposure of their
TM domain could explain their spontaneous insertion into
the PV membranes following secretion. In this regard, it is
important to consider that the vacuolar space constitutes
an environment enriched by extensive exocytosis of
parasite proteins, including a cyclophilin homologue that
may participate in protein refolding (35). Yet, the sole
exposure of a GRA TM domain is not sufficient for
membrane insertion because SAG1/GRA5TM/GRA5-HF
was unable to insert into the PV membrane. Interactions
between the GRA5 Nt domain and the specific vacuolar
cofactors (Figure 8) could thus contribute to post-secre-
tory membrane insertion. Because the majority of vacuolar
components are delivered from the DG at the same time
as GRA5, it is likely that establishment of new interactions
between the GRA5 Nt domain and the vacuolar proteins
relies on conformational modifications of GRA5 and/or of
protein partners following their secretion. Such changes
could be induced by new environmental conditions within
the PV. Alternatively, given that the PV membrane is
a mixed compartment derived from both the host cell
and the parasite, it is important to consider the possibility
of an interaction with host-cell components. Some of
these components could constitute accessory partners
of GRA proteins during their translocation into the PV
membrane. Of particular interest are the GPI-anchored
proteins of host origin. These proteins are selectively
included in the PV membrane during the invasion process,
while the vast majority of host integral membrane proteins
are excluded from it (36,37). Moreover, these host-derived
GPI-anchored proteins are likely to contribute to the
ordering of PV-membrane-associated proteins into mem-
brane microdomains (36,37). Therefore, another possibil-
ity, not necessarily exclusive from the previous one, is that
the GRA5 Nt domain would function as a specific raft-
targeting signal in a manner similar to the proteinaceous
raft-binding determinants found either within the Nt ecto-
domain of the prion protein (38) or within the juxtamem-
brane region of the epidermal growth factor receptor
ectodomain (39). Physiologically, such interaction with
host-cell components would be of particular evolutionary
interest in terms of host–parasite cross talk.
In conclusion, this work provided evidence for a novel
specialized sorting mechanism evolved by T. gondii to
ensure trafficking of single-pass TM proteins within its
host-cell residence. Such diversity in sorting mechanisms
is needed to comprehend the specialization of secretory
pathway in a cell-specific fashion.
Materials and Methods
Parasites, cell culture and transfectionTachyzoites of the RH hxgprt� strain (40), the mutants Dgra5 (41) and
Dsag1 (42) and transgenic lines derived from these strains were maintained
by serial passages in human foreskin fibroblasts [HFF, American Type
Culture Collection (ATCC)-CRL 1634] in DMEM (GibcoBRL) supplemented
with 1 mM glutamine, 10% FBS, 50 U/mL penicillin and 50 mg/mL strepto-
mycin (referred to as D10). Parasite transfection was performed by
electroporation, and phleomycin was used to select mutants derived from
the Dsag1 strain as previously described (43), whereas those derived from
the RH hxgprt� and Dgra5 strains were selected using both xanthine and
mycophenolic acid (40). HEK 293-T cells (ATCC-CRL 11268) were also
maintained in D10 and transfected using the calcium phosphate precipita-
tion method (44).
AntibodiesThemammalian protein CD46was detected using either the TRA-2-10 mAb
that recognizes the first ligand-binding motif in the CD46 Nt region (28) or
an anti-CD46 rabbit polyclonal antibody, both donated by Dr K. Liszewski
(Washington University School of Medicine, St Louis, MO, USA). The
various fusion proteins were detected using an anti-HA rabbit serum (gift
fromM.A. Hakimi, CNRS, UMR 5163-Universite Joseph Fourrier, Grenoble,
France), the mAbs BioM2 anti-FLAG� (Sigma-Aldrich), TG 17–113
Traffic 2008; 9: 1665–1680 1677
Trafficking to the Toxoplasma Parasitophorous Vacuole
anti-GRA5 that recognizes the Nt region of GRA5 (15,45), TG 05–54 anti-
SAG1 (46) and an anti-GRA5 Nt mouse serum (15). The mAbs TG 17–43
anti-GRA1 (45) and TG2H11 anti-GRA3 (47) as well as an anti-GRA3 rabbit
serum were also used.
Plasmid constructsSpecific primers (Table S1) were designed from the sequences of GRA5
(25), CD8 (48), CD46 (27) and SAG1 (49).
DNA constructs for transfection into HEK cellsThe coding regions of GRA5 and CD46 were cloned into a pBluescript KSþ
vector modified by the insertion of a HA-FLAG (HF) tag (50). These vectors
were used as templates to amplify GRA5-H (GRA5 in fusion with the HA
tag), GRA5-HF (GRA5 in fusion with the HA-FLAG tag) and CD46-H. After
cleavage with both BamHI and XhoI, the polymerase chain reaction (PCR)
fragments were cloned into the vector pcDNA3.1 (Invitrogen Life Sciences)
under the control of the cytomegalovirus promoter. The MLO2-F vector
was provided by Dr M.A. Hakimi.
DNA constructs for transfection into T. gondiiThe CD46 open reading frame (ORF) was cloned into the modified KSþ
under the control of the strong GRA1 promoter and its 50-untranslated
region (50-UTR) (50). All the other fusion constructs were cloned under the
control of the regulatory regions [promoter, both 50-UTR and 30-untranslated
region (30-UTR)] of endogenous GRA5. To obtain the constructs GRA5/
CD8TM/GRA5 and GRA5/CD46TM/GRA5, specific fragments of GRA5, CD8
or CD46 were amplified using primers containing 15–20 bases comple-
mentary to the DNA fragment to be amplified and tailed with 15–20 bases
complementary to the adjacent DNA fragments in the final construct,
allowing hybridization of adjacent fragments in further PCRs. The final
products, including the GRA5 regulatory regions, were then cloned into the
BamHI–NotI sites of the pBluescript SKþ vector expressing the selection
marker HXGPRT (provided by Dr D.S. Roos, University of Pennsylvania,
Philadelphia, PA, USA). For all the other constructs, the GRA5 regulatory
regions were first amplified and cloned into the modified pBluescript KSþ
vector bearing the HF tag. Following amplification of specific fragments
from the GRA5, SAG1 or CD46 ORF, the final fusion PCR products were
obtained using the same hybridization PCR technique. The final products
were cloned into the SmaI and EcoRI sites of the modified KSþ plasmid, in
frame with the GRA5 50-UTR and the 30-HF tag.
Prediction of membrane-spanning regions
and their orientationThe TMHMM and TMPRED softwares (http://www.cbs.dtu.dk/services/
TMHMM-2.0/ and http://www.ch.embnet.org/software/TMPRED_form.html)
available at the Expert Protein Analysis System proteomics server (ExPasy
server) (http://www.expasy.org/) were used to predict the topology of GRA
proteins in mammalian cells.
Immunofluorescence stainingHFF cells were grown on 12-mm coverslips in 24-well plates until
confluency and then infected. Overnight infected cells were washed in
PBS, fixed for 20 min in 5% formaldehyde in PBS at room temperature and
permeabilized for 10 min either selectively with 0.002% saponin (8) or
completely in 0.1% Triton-X-100. Extracellular parasites were left to adhere
to a cell monolayer for 30 min at 378C and permeabilized with 0.1% Triton-
X-100 following fixation. Transfected HEK cells were either permeabilized
with 0.1% Triton-X-100 after fixation or processed as living cells. After
rinsing, cells were incubated with primary antibodies and with anti-
immunoglobulin G (HþL) goat secondary antibodies coupled to Alexa
(Invitrogen, Molecular Probes). Coverslips were mounted using Prolong
antifade reagent (Molecular Probes) and observed using a Zeiss Axioplan II
equipped for phase-contrast and epifluorescence microscopy. Photographs
were taken at the magnification�100 using a Zeiss AxiocamMRm coupled
to the AXIOVISION 4.5 software and processed with ADOBE PHOTOSHOP 6.0.
Cell fractionationFor HEK cell fractionation, cells were lysed by syringing through a 22-gauge
needle. After removal of nuclei and debris by a 10-min centrifugation
at 1000 � g, the supernatant was centrifuged for 30 min at 130 000 � g.
The resulting membrane pellet was dispersed in PBS and submitted to
treatment with either 1 M NaCl, 0.1 M sodium carbonate (pH 11.3), 6 M urea
or 1% NP-40. After incubation on ice for 30 min, the samples were
centrifuged at 130 000 � g for 30 min to separate solubilized proteins
from residuals.
Cell fractionations of both extracellular and intracellular parasites were
performed as described previously (15): extracellular parasites were lysed
by three freeze/thaw cycles, and the lysate was submitted to Triton-X-114
extraction (51). Briefly, the lysate was treated with 10% Triton-X-114, and
after removal of the insoluble material, the aqueous phase was separated
from the detergent phase by a 10-min incubation at 378C. The parasite
lysate was also centrifuged for 10 min at 2500 � g. The low-speed
supernatant was submitted to ultracentrifugation at 100 000 � g for
1.5 h. The LSP resuspended in 50 mM Tris (pH 8.0) was treated with
denaturing agents (6 M urea or 1% NP-40) for 30 min at 48C, followed by
a 1.5-h ultracentrifugation at 100 000 � g. For intracellular parasites, over-
night infected HFF cells were mechanically disrupted by syringing through
a 27-gauge needle. After removal of intact parasites and cell debris by
centrifugation at 2500 � g for 10 min, the soluble fraction was separated
from themembrane-associated fraction by ultracentrifugation at 100 000 � g.
Aliquots of the membrane pellets were treated with 6 M urea or 0.1%
NP-40 for 30 min at 48C, followed by centrifugation at 100 000 � g, as
described previously (8). In all fractionation experiments, supernatants
were concentrated by trichloroacetic acid or acetone precipitation. Each
experiment was repeated three times.
Western blottingProteins were boiled for 2 min in SDS–PAGE sample buffer, separated by
electrophoresis on 13% polyacrylamide gels and transferred to nitrocellu-
lose membranes. Immunologic detection was achieved using appropriate
horseradish-peroxidase-conjugated secondary antibodies. Peroxidase activ-
ity was visualized by chemiluminescence using the Supersignal ECL
system (Pierce Chemical).
Acknowledgments
The authors thank Drs J. Dubuisson, M.A. Hakimi, K. Liszewski and D.S.
Roos for sharing reagents and acknowledge the contribution of E. Glyde for
the first constructs. They are also very grateful to Drs M. Meissner and
J. Gagnon for their critical reading of the manuscript. This study was
supported by the CNRS and the AC program ‘Dynamique et Reactivite des
Assemblages Biologiques’ (DRAB04/027). C. G. was the recipient of a PhD
fellowship from the French Ministry of Research.
Supporting Information
Additional Supporting Information may be found in the online version of
this article:
Figure S1: DG targeting of GRA5/CD46TM/CD46-HF and SAG1/8aa/
GRA5TM/GRA5-HF in extracellular parasites by immunofluorescence
double labeling. Dgra5 parasites expressing GRA5/CD46TM/CD46-HF (A)
or Dsag1 parasites expressing the SAG1-derived construct (B) were
permeabilized with Triton-X-100 and incubated with the anti-HA serum.
Co-detection of GRA3 (using the anti-GRA3 mAb) or GRA5 (using the anti-
GRA5 mAb) is presented. Bars, 2 mm.
Table S1: Sequence of the primers used in this study
1678 Traffic 2008; 9: 1665–1680
Gendrin et al.
Please note: Wiley-Blackwell are not responsible for the content or
functionality of any supporting materials supplied by the authors. Any
queries (other than missing material) should be directed to the correspond-
ing author for the article.
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