By
From the Lymphocyte Biology Section, Laboratory of Immunology, National Institute of Allergy and Infectious Diseases, National Institutes of Health, Bethesda, Maryland 20892-1892
Leucine-based signals in the cytoplasmic tail of invariant chain (Ii) control targeting of newly
synthesized major histocompatibility complex class II molecules to the endocytic pathway for
acquisition of antigenic peptides. Some protein determinants, however, do not require Ii for
effective class II presentation, although endocytic processing is still necessary. Here we demonstrate that a dileucine-based signal in the cytoplasmic tail of the class II chain is critical for this
Ii-independent presentation. Elimination or mutation of this signal reduces the rate of re-entry
of mature surface class II molecules into the endocytic pathway. Antigen presentation controlled by this signal does not require newly synthesized class II molecules and appears to involve determinants requiring only limited proteolysis for exposure, whereas the opposite is true for Ii-dependent determinants. This demonstrates that related leucine-based trafficking signals
in Ii and class II control the functional presentation of protein determinants with distinct processing requirements, suggesting that the peptide binding sites of newly synthesized versus mature class II molecules are made available for antigen binding in distinct endocytic compartments under the control of these homologous cytoplasmic signals. This permits capture of protein fragments produced optimally under distinct conditions of pH and proteolytic activity.
MHC class II molecules present to CD4+ T cells peptides derived from proteins entering the endosomal-
phagosomal system (1, 2). Invariant chain (Ii)1 aids in assembly and transport of newly synthesized class II molecules
and also protects the class II binding site from either improper folding or premature interaction with protein ligands in the secretory pathway (3). This same type II membrane protein also contains a pair of leucine-based signals in
its cytoplasmic tail that promote its trafficking and that of
associated newly synthesized class II molecules through
early endocytic compartments to dense organelles of the
endocytic pathway (4). Class II capture of antigenic fragments in these class II-rich organelles (MIIC) requires proteolytic removal of associated Ii (11), particularly of the
class II-associated invariant peptide (CLIP) fragment (12, 13) whose replacement in the binding site by antigenic peptides is facilitated by the MHC-encoded DM molecule
(14).
Although this general scheme of Ii-regulated class II synthesis, trafficking, and antigen capture is supported by numerous studies using transformed cell lines, transfected
cells, and cells of wild-type and Ii-deficient mice, not all
peptide determinants require Ii for effective presentation,
although they still require processing in acidic compartments
(17). Distinct determinants in even a single protein antigen (hen egg lysozyme, HEL) can show differential dependence on Ii for their effective presentation (19). Other
studies have demonstrated that some antigenic determinants are dependent on new protein synthesis or secretory
pathway export for their presentation, whereas others are
not (22), providing a parallel to the Ii data in terms of
the involvement of newly synthesized (Ii-associated) versus
mature class II (Ii-free) in effective presentation of these
different antigenic fragments.
These observations of Ii-independent, endosomal processing-dependent presentation of some antigenic determinants are consistent with the accumulation of class II proteins in intracellular vesicles with the characteristics of late
endosomes/lysosomes in some cells lacking Ii coexpression
(26). Functional studies have also shown that truncation
of the class II These various findings suggest that two distinct pathways
for class II-dependent antigen presentation exist, and imply
that separate protein localization signals in the cytoplasmic
tails of Ii and class II play important roles in these events.
The identity of the localization signal(s) in class II chains
has not been established, although Smiley et al. have hypothesized that conserved dileucines in the class II Reagents.
HEL (cat No. L6876, lot No. 89F8275), diethylamino-ethyl-dextran, chloroquine, and dimethyl sulfoxide were
obtained from Sigma Chemical Co (St. Louis, MO). LPS was from
DIFCO (3122-25-8; Detroit, MI), recombinant murine IFN- Constructs.
The cDNA constructs coding for the wild-type Transient Transfection.
Cos 7.2 cells were transiently transfected with DNA of the cDNA constructs coding for the Stable Transfectants.
Rat basophil leukemia cells (RBL)-5 were
stably transfected by electroporation with cDNA constructs coding
for the following combinations: FACS® Staining.
The Ak expression level on transfectants
was measured by staining the surface using a saturating amount of
H116.32 antibody (40) on ice for 30 min. A FITC-conjugated
rabbit anti-mouse IgG (Jackson Laboratory, Bar Harbor, ME)
was used to detect the bound H116.32. Ii expression by the transfectants was measured by intracellular staining with IN-1 (41) and
an FITC-conjugated goat anti-rat IgG (Jackson Laboratory). The
fluorescence intensity was measured on a FACScan® flow cytometer
(Becton-Dickinson, Mountain View, CA). Transfectants with
comparable levels of surface class II and intracellular Ii in appropriate combinations were chosen for use in functional experiments.
Antigen Presentation Using B Cells and M Antigen Presentation Using Transfectants.
COS or RBL transfectants were seeded onto 96-well plates at 5 × 104 cells/well in
complete RPMI medium. HEL was added to the cells at various
concentrations followed by T cell hybridomas (5 × 104/well).
The cultures were incubated at 37°C for 18 to 24 h and IL-2
measured in the supernatants. No fixation was used for presentation assays with these transfectants.
IL-2 ELISA.
The IL-2 level in culture supernatants was
measured by sandwich ELISA performed as previously described
(42). Under these conditions, the assay is linear to an OD of ~3.
Absolute levels of IL-2 produced in the various experiments were
generally between 10 and 100 U/ml.
Immunofluorescence Microscopy and Class II Internalization Assay.
To evaluate internalization of surface class II, a modified
version of the procedure described by Roche et al. (43) was used.
Cells were grown on coverslips, washed twice with cold, complete DMEM, and reacted with saturating amounts of 10-2.16 antibody for 2 h on ice to ensure monovalent binding. Cells were then washed extensively to remove unbound antibody. Washed
cells were either left at 4°C or warmed to 37°C for various periods of time extending up to 150 min. After the appropriate time
interval, the cells were fixed with 10% paraformaldehyde for 10 min at room temperature, permeabilized with 0.2% saponin for
30 min, and then blocked with 2% BSA at 4°C overnight. Samples were then washed with PBS and stained using rabbit anti-mouse
IgG antibodies conjugated with FITC (Jackson Laboratory). To
exclude the possible class II-independent uptake of antibody into
endocytic structures, untransfected RBLs were treated in the same
manner. Coverslips bearing stained cells were mounted and analyzed using a confocal microscope (MRC1024; Bio Rad Labs.,
Hercules, CA).
Many previous
studies have shown varying sensitivities of class II antigen
presentation to metabolic inhibitors, or distinct requirements
for particular cell types, for new protein synthesis, or for Ii,
suggesting the existence of multiple distinct pathways for
antigen processing and presentation by class II molecules. Most of these, however, have involved comparisons between different proteins or distinct MHC class II alleles. To
more systematically explore this issue, we have turned to a
well-studied model antigen. HEL contains three distinct
determinants (34-45, 46-61, and 116-129) that bind to the
same class II molecule, A
We next reexamined the Ii dependence of presentation of the
three determinants. The lack of a requirement for newly
synthesized proteins suggested that Ii-associated class II molecules would not be required for presentation of 34-45 or
116-129, in contrast to 46-61. COS cells were transiently
transfected with plasmid constructs encoding I-Ak
In certain cells, leucine-based
targeting signals in the Ii cytoplasmic tail are important for
the endocytic accumulation of newly synthesized class II
molecules (4). However, this is not true in all cells, and
the localization of class II to late endocytic structures has
been observed in several cell expressing class II without Ii
(26). Pinet et al. have reported that presentation of a
hemagglutinin determinant by DR is independent of Ii,
but requires uncharacterized internalization signals in the
cytoplasmic tails of the class II
In discussing their evidence that the class
II Table 1.
Leucine-Based Motif in the Class II
Based on the results of Pinet et al. showing that
deletion of either the class II
The 34-45, 46-61, and 116-129 determinants of HEL lie in very different locations in the folded
structure of the intact HEL protein, with 116-129 being
most superficial, 34-45 being partially buried, and 46-61 lying at the core of the protein in a structure maintained by
disulfide bonds. Presentation of the 46-61 determinant of
HEL requires the reducing environment found in lysosomes (44, 45) and this correlates with where newly synthesized class II-Ii complexes accumulate before Ii digestion and CLIP removal (10, 47). On the other hand,
the inability of Ii to rescue presentation of 116-129 in cells
expressing tail-mutated class II suggests that this determinant may not be available in such highly acidic, dense, endocytic organelles. In this regard, Frosch et al. have reported that IFN-
The various organelles comprising the endosomal/lysosomal pathway have distinct pHs, protease contents, and
capacities to promote protein unfolding (53). These properties and the rate of luminal content transfer among these
organelles also vary for cells of distinct tissue origin or state
of activation. These differences all affect the function of the
class II antigen presentation system by influencing the
availability of specific sequences within any given protein
for binding to MHC class II molecules in the same compartment. Likewise, heterogeneity in protein structure and
binding site occupancy also modify the capacity of class II molecules to capture protein/peptide substrates in these organelles. In part, ensuring the presentation of diverse antigenic ligands is promoted by the simultaneous expression
of multiple class II proteins in the cells of a single individual. However, because the different proteins of pathogens
may vary from those that are highly sensitive to protease attack to some requiring extremely harsh conditions for digestion, it also makes sense that the immune system would
evolve the means to enable these polymorphic class II proteins to sample several endocytic organelles for suitable ligands. The data presented in this paper suggest that two
different cohorts of MHC class II molecules sample endocytic content in an overlapping pattern that permits ligand
capture from both early and late endocytic compartments.
The control of protein trafficking necessary for the operation of these two presentation pathways lies in related cytoplasmic leucine-based signals, one of which is characterized
in this study. However, it is the timing of binding site
availability that appears to actually distinguish where class II
molecules in each pathway most effectively acquire antigen.
Previous studies have shown that leucine-based motifs
within the cytoplasmic tail of Ii are essential for effective localization of newly synthesized class II-Ii complexes to late
endocytic/lysosomal organelles (7). These leucine-containing signals are similar to others found in proteins such as
the TCR CD3 In contrast, two other determinants within the same HEL
molecule, at residues 34-45 and 116-129, show a very different behavior. Neither is well presented by activated
macrophages, and partial inhibition of protease activity improves presentation of these determinants in such macrophages, but not in less proteolytically active B cell blasts.
Inhibition of the trafficking of newly synthesized proteins
had at best modest effects on the presentation of these determinants and neither required Ii for their presentation.
Taken together, these data argue that both of these determinants are available to a cohort of class II molecules distinct
from that associated with Ii. Because control experiments
showed that endocytic processing was involved, these data
suggested that exposure and capture of these regions of
HEL occurs in early endocytic compartments and involves
mature class II molecules. This in turn led to an attempt to
understand how a surface pool of mature class II molecules could gain access to such endocytic organelles. Sequence
alignment revealed a highly conserved GLL motif in the
tail of class II The steady state distribution of class II in transfectants with
wild-type or signal-minus class II molecules did not differ grossly. Internalization experiments, however, revealed a
clear effect of the mutations, namely a significant delay in
the rate of internalization of surface class II into the endocytic pathway. Previous results have shown that class II binding sites lose their function rapidly at physiological temperature in the absence of ligand engagement (3, 58, 59). If the
major pool of class II sites involved in acquisition of determinants such as HEL 116-129 become empty on the cell
surface before internalization, delayed uptake would result
in such molecules becoming incapable of peptide binding
by the time they reached the site of antigen availability. Alternatively, the class II molecules involved in HEL 116-129 presentation may only shed their original peptide upon exposure to the mildly acidic pH of early endosomes, whereupon they would be immediately available to bind new
ligand. Substantially decreasing the pool of such molecules
reaching the endocytic pathway at any point in time could
then markedly reduce antigen presentation. Both of these
effects may in fact contribute to the functional defect observed with the mutant class II chains lacking the GLL motif. This model also can account for the recent findings of Smiley et al. (60), who demonstrated an increased density of CLIP-class II complexes on cells expressing class II molecules with a The timing of binding site availability appears to play a
predominant role in dictating which set of determinants is
presented by which cohort of class II molecules. The binding sites of Ii-associated class II become available mainly in
the MIIC via the action of cathepsins and DM, and this biases these dimers for capture of those determinants able to
survive transport through earlier endocytic compartments.
These same class II molecules are ineffective in the capture
of determinants present only in early endosomes because they do not have an accessible binding site in that location. Conversely, mature class II molecules, using a very homologous targeting signal to traffic to the same or a similar set
of early and late endocytic organelles, primarily bind those
ligands available in early endocytic compartments because
the binding site is accessible there. Some determinants such
as 34-45 appear to be available in more than one location,
permitting capture by class II via either pathway.
The added breadth of determinants presented to CD4+
T cells through use of a recycling pathway has obvious advantages for the immune system. Viruses enter cells by fusing with or disrupting either plasma or early endosomal
membranes. The relevant viral proteins often undergo
structural changes and remain in these membranes when the
viral genome enters the cytosol (62). Such refolded proteins
may be highly susceptible to proteolysis shortly after viral
entry, and the presentation of determinants derived from these
proteins would help elicit a T cell response at the earliest
time after viral infection. Data consistent with this suggestion come from the work of Pinet et al. (31), who showed that a determinant from influenza hemagglutinin was presented in an Ii-independent, class II tail-dependent manner.
Another rationale besides sensitivity to proteolysis for such
a pathway is the capture of ligands unable to bind tightly to
class II at the highly acidic pH of the MIIC.
The results presented here, together with the recent
study of Pinet et al. (31) help rationalize a contradictory literature concerning the role of newly synthesized versus
mature class II molecules and of Ii in class II presentation to
T cells. They also emphasize the important differences in
processing and presentation of the same protein by different
cell types, as evidenced by the inability of activated macrophages to present 34-45 or 116-129 without addition of
an inhibitor of lysosomal function. The demonstration that
cytoplasmic signals in the class II chain cytoplasmic tail affects antigen presentation to some autoreactive T cell hybridomas even by
cells producing Ii (29), although other determinants remain well presented by the same mutant class II molecules (30).
In experiments with intact influenza particles, truncation of
the class II
or
cytoplasmic tails selectively interferes
with presentation of a hemagglutinin determinant whereas
a matrix protein-derived determinant is instead dependent
on Ii for presentation (31). These studies revealed a correlation between hemagglutinin presentation and the involvement of the class II cytoplasmic tails in entry of mature surface class II into the endocytic pathway. Similarly, Smiley
et al. have demonstrated in a mouse model system that the cytoplasmic tails of class II molecules play a key role in the presentation of some antigenic determinants (32).
chain
tail are likely to be involved (32). In addition, the role of
such localization signals in class II has not been directly compared to that of Ii signals in presenting different antigenic
determinants from a single protein molecule. Finally, little
information is available on what predisposes presentation of
different determinants within a given protein antigen to
dependence on one or the other of these pathways. In the
present study, we have used the well-characterized HEL
antigenic model (33) to examine these issues. We demonstrate that the dileucine-containing sequence in the class II
chain noted by Smiley et al. (32) is critical for Ii-independent presentation of two HEL determinants, whereas a
third determinant in the same protein requires the tail signals in Ii for its effective presentation. In combination with
earlier observations, our data support a model of class II
presentation involving (a) Ii-dependent capture of buried
antigenic determinants in lysosome-related, highly proteolytic compartments by newly synthesized class II molecules and (b)
chain-tail dependent antigen capture of
more superficial determinants in less proteolytic (early) endocytic organelles by mature, recycling class II. These two
pathways together provide a mechanism for optimal presentation of the multiple determinants often contained in
proteins entering the endocytic pathway.
from PharMingen (San Diego, CA), brefeldin A (BFA) from Epicentre Technologies Corp. (Madison, WI), leupeptin from Boehringer Mannheim (Indianapolis, IN), and G418 (Geneticin) from
GIBCO (Gaithersburg, MD). The peptides HEL 46-61 (NTDGSTDYGILQINSR), HEL 34-45 (FESNFNTQATNR), and HEL
116-129 (KGTDVQAWIRGCRL) were synthesized and purified by HPLC before use by the National Institute of Allergy and
Infectious Diseases Peptide Synthesis Facility (Rockville, MD).
or
chain of Ak in the plasmid CDM8 (34) and the cDNA coding for murine Ii31 in the plasmid pcEXV3 have been previously
described (35). A construct coding for the
chain of Ak with an 18 amino acid deletion at the COOH-terminus was made by placing
a stop codon after the codon encoding isoleucine 220, as described elsewhere (29). The construct was placed into the expression plasmid vector pCDL-SR (36), provided by Dr. J. Bonifacino (National Institute of Child Health and Development, National Institutes of Health). The
chain with this COOH-terminal 18 amino acid deletion is designated as
CT18. A construct coding for a
chain with the cytoplasmic leucines at positions 236 and 237 each changed to alanine was made by oligonucleotide-directed mutagenesis using PCR, and cloned into the pCDL-SR vector.
The 5
primer was 5
GTC AGA GCT CGA GTG TGC CTT
AGA GAT GGC TC 3
and the 3
primer was 5
GAG CAC
CAG ATC TCA CTG AGC TGC CCC TGC TGG AGG
AGG GCC ACG AGG TCC 3
; mutagenesis was performed as
described (37). The resultant mutant
chain was designated as
CTAA. The sequences of all constructs were confirmed as correct using an automated DNA sequencer.
and
chain of Ak alone (3 µg each) or together with DNA for the cDNA
coding for murine Ii31 (10 mg), using a diethyl-amino-ethyl-
dextran method as previously reported (38).
/
,
/
CT18, and
/
CTAA,
with or without DNA for the construct encoding mIi31, using a
modified procedure from Engel et al. (36). 18 µg of DNA encoding each chain of class II and 2 µg of pfneo (39) conferring resistance to G418 were used for each electroporation. In the case of
Ii cotransfection, an additional 54 µg of DNA encoding Ii was
added. Transfected cells expressing the desired proteins were
cloned by limiting dilution.
s as APCs.
Single cell
suspensions from the spleens of CBA mice (Jackson Laboratory;
8-10 wk old, female) were made and red blood cells removed using ammonium chloride-potassium lysing buffer (Biofluids Inc.,
Rockville, MD). The splenocytes were cultured for 2 d in the
presence of 10 µg/ml LPS in RPMI medium containing 10%
FCS. The B cell blasts were then harvested and used as APCs. For
M
preparation, CBA mice were injected intraperitoneally with
4 ml thioglycollate (National Institutes of Health Media Unit,
Bethesda, MD) and 4 d later, the exudate M
s were harvested by
washing the peritoneal cavity with ice-cold PBS. The exudate
cells were incubated in the wells of 96-well plates for 2 d in complete RPMI 1640 medium containing 20 U/ml of murine IFN-
.
The IFN-
activated M
s (IFN-
M
s) were then used without
harvesting as APCs. In the antigen presentation assay, the B cell
blast or M
APCs were pulsed with various concentrations of intact HEL antigen for 6 h, and then fixed with 1% paraformaldehyde for 20 min followed by neutralization with 0.1 M glycine.
The fixed APCs pulsed with antigen (5 × 104 cells/well) were
mixed with antigen-specific T cell hybridomas (5 × 104 cells/well)
in a total volume of 200 µl in complete RPMI medium containing 2-ME. The cultures were incubated for 18-24 h and IL-2 production in the supernatant was measured by ELISA. The hybridoma 3A9.1 specific for HEL epitope 46-61 was from Dr. Paul
Allen (Washington University, St. Louis, MD), and hybridomas
3B11.1 and 1B9.1 specific for HEL 34-45 and 116-129 respectively were provided by Dr. L. Adorini (Roche Milano Ricerche,
Milan, Italy). For inhibition of antigen presentation, APCs were
pretreated with various concentrations of BFA for 15 min, chloroquine for 30 min, or leupeptin for 2 h before HEL was added.
All APCs were then pulsed with 50 µM of HEL for 6 h in the
continued presence of inhibitor before fixation and addition to T
cells. Presentation of peptide was also assessed in parallel by adding the indicated concentration of peptide to the cells for the
same 6-h period before washing and fixing.
The Presentation of Three Distinct Peptide Determinants Within
HEL That Require Active Endocytic Processing Shows Differential
Dependence on Newly Synthesized Proteins.
kA
k, with a different dependence
on the coexpression of Ii (19) or lysosome-dependent disulfide bond reduction and fragmentation of the HEL protein
(44, 45). We first verified that all three determinants require
pH -sensitive intracellular processing (Fig. 1). The lysosomotropic amine chloroquine inhibits the presentation of all
three determinants by normal B cell blasts (Fig. 1 B). Furthermore, if these B cell APCs are chemically fixed before antigen exposure, they present synthetic peptides and denatured HEL, but not intact, nondenatured HEL (data not
shown). These results indicate that T cell recognition of all
three determinants requires active intracellular processing
of the native protein. Despite this, when BFA is used to
block export of newly synthesized proteins from the endoplasmic reticulum, only the presentation of HEL 46-61 is
strongly inhibited (Fig. 1 C). This suggests that presentation of HEL 34-45 and 116-129 may involve a pool of mature class II molecules.
Fig. 1.
The 34-45, 46-61, and 116-129 determinants in HEL all require endocytic processing for presentation, but only 46-61 requires newly synthesized proteins. B lymphoblasts were incubated with the indicated concentrations of HEL in standard medium for 6 h or with 50 µM
HEL for 6 h in the presence of the indicated concentrations of drug. The
B cells were then fixed and used as APCs with T hybridomas specific for
each determinant. IL-2 production at 24 h is presented as OD obtained
using an IL-2-specific capture ELISA. The data represent one of three independent experiments.
[View Larger Version of this Image (24K GIF file)]
and
chains or I-Ak plus mouse Ii 31, and the transfectants were
monitored for class II surface expression levels by FACS®.
All transfectant pools used in these experiments expressed
equivalent levels of Ak as detected with mAb H116.32 (data
not shown), in agreement with our earlier data showing
that in COS, Ii coexpression does not noticeably increase
surface levels of Ak (38). COS transfectants expressing Ak
alone efficiently present 34-45 and 116-129, but not 46-61. Cotransfection with Ii dramatically increases the presentation of 46-61 (Fig. 2 A), but has little effect on presentation
of 34-45 and 116-129 (Fig. 2, B and C). Again, these data
are consistent with studies using rat-2 transfectants and the
differential requirement for protein export from the secretory pathway for presentation of the three determinants.
Fig. 2.
Only the 46-61 determinant is highly dependent on
Ii coexpression with Ak for its effective presentation. COS cells
transfected with cDNA expression constructs encoding either
Ak or Ak and the p31 form of
mouse Ii were used as APCs
with the indicated concentrations of HEL for stimulation of
T hybridomas specific for the
indicated determinants of HEL.
IL-2 production at 24 h is presented as OD obtained using an
IL-2-specific capture ELISA. The
data represent one of three independent experiments.
[View Larger Version of this Image (19K GIF file)]
k and A
k in Presentation
of the Three HEL Fragments.
and
chains (31). Smiley
et al. (32) have also shown a role for class II cytoplasmic
tails in antigen presentation and suggested that a dileucinebased motif in the
chain may be involved in this function. To assess whether signals in the cytoplasmic tails of
the Ak molecule itself are involved in the presentation of
34-45 or 116-129, RBLs were stably transfected with constructs expressing various combinations of wild-type Ak or
Ak tail deletion mutants with or without Ii, and clones with
comparable levels of surface class II and intracellular Ii selected. As with COS and rat-2 cells, efficient presentation
of 46-61, but not 34-45 and 116-129, by wild-type Ak expressed by RBLs depends on Ii (Fig. 3). Although cells expressing wild-type Ak alone can effectively stimulate 34-45-
and 116-129-specific T cells after HEL exposure, truncation
of the
chain tail prevents this presentation. Examination
of presentation of the three determinants by cells with the
tail deleted Ak coexpressed with Ii revealed that each determinant has a distinctive combination of requirements for
either Ii or the
chain tail. The 46-61 and 34-45 determinants are both presented well by cells expressing I-Ak with
a truncated
chain tail together with Ii, but Ii expression does not rescue the ability of
tail deleted class II molecules to present 116-129. Therefore, the efficient presentation of 46-61 requires Ii irrespective of the presence or absence of the class II
chain tail, presentation of 34-45 requires either intact class II tail or Ii and the class II
tail is
required for the presentation of 116-129 and this function
cannot be replaced by Ii. Similar data were obtained using
transiently transfected COS cells (data not shown).
Fig. 3.
Differential requirements for Ii coexpression and for
the cytoplasmic tail of the class II
A chain in the presentation of distinct determinants of HEL.
RBLs stably transfected with
constructs encoding the indicated A
k and A
k proteins with
or without Ii p31 were used as
APCs for mouse T hybridomas
specific for the indicated determinants. IL-2 production at 24 h is
presented as OD obtained using
an IL-2-specific capture ELISA.
The data represent one of three
independent experiments.
[View Larger Version of this Image (21K GIF file)]
Chain Is Required for Effective Ii-independent Antigen Presentation.
chain tail contributes to effective antigen presentation,
Smiley et al. have noted the existence of a conserved dileucine in this segment of the protein, and suggested that it may
be part of a targeting motif (32). We have independently
compared the sequences of multiple class II
chains from
various species, looking for highly conserved sequences and
also for sequences resembling either the known leucine- or
tyrosine-containing signals mediating endocytic protein targeting. As shown in Table 1, like Smiley et al., we identified the same conserved dileucine near the COOH terminus of the
chain, preceded by an invariant glycine, giving
rise to the sequence GLL that closely resembles one of the
two localization signals in Ii (GLI in the mouse). This sequence in class II is also spaced only one residue further
from the end of the transmembrane domain as compared to
the comparable Ii sequence; previous studies have shown
that the distance of a signal from the membrane can play an
important role in its traffic control function (46). To test
directly whether these dileucines are a critical part of a
functional targeting motif in the class II tail, a mutant cDNA was prepared that encodes a complete A
k chain except for substitution of the two cytoplasmic leucines with
alanines (
CTAA). This construct was stably transfected
into RBLs along with plasmids encoding wild-type A
k
chains, with or without the construct for Ii. The ability of the transfected cells to present the three HEL determinants
was compared to the wild-type Ak transfectants (Fig. 4). Like
deletion of the entire
chain tail, substitution of the two
leucines with alanine prevents the presentation of 34-45 and 116-129 in cells lacking Ii, and Ii coexpression with
class II containing
CTAA can rescue presentation of 34-45 but not 116-129.
Chain
Cytoplasmic Tail
Species/protein
Cytoplasmic tail sequence
Human DR
RNQKGHSGLQPTGFLS
Human DQ
RSQKGPQGPPPAGLLH
Chimp DR
RNQKGHSGLQPTGFLS
Mouse I-A
RSQKGPRGPPPAGLLQ
Mouse I-E
RNQKGQSGLQPTGLLS
Rat I-A
R-QKGPQGPPPAGLLQ
Rat I-E
RSQKGNSGLQPTGLLN
Dog DR
RNQKGHSGLQPTGLLS
Chicken
RGQKGRPVAAAPGMLN
Mouse I-A
RSQKGPRGPPPAGLLQ
Mouse Ii
RSCREPERPRNGLIPLQEHNSILDRQDDM
Alignment of the sequences in the cytoplasmic tails of MHC class II
chains of various species (63), and of mouse class II A
and mouse Ii.
For Ii, the sequence is shown C
N from left to right because this is a
type II membrane protein shown in its proper orientation relative to
the membrane and the adjacent class II sequence. The double-headed
arrow points to an invariant glycine residue that precedes the conserved
leucine-containing pair of amino acids.
Fig. 4.
Mutation of the
conserved LL sequence at the
COOH terminus of the A
chain cytoplasmic tail eliminates
the ability of this protein to mediate Ii-independent presentation
of either the 34-45 or 116-129 determinants of HEL. RBLs stably transfected with constructs encoding the indicated A
k and
A
k proteins with or without Ii
p31 were used as APCs for
mouse T hybridomas specific for
the indicated determinants. IL-2
production at 24 h is presented as
OD obtained using an IL-2-specific capture ELISA. The data
represent one of three independent experiments.
[View Larger Version of this Image (17K GIF file)]
Chain Cytoplasmic Leucines with Alanines Delays, but does Not Prevent, Ak Internalization into Endosomes.
or
tails precluded internalization of surface DR (31), we expected that the
CTAAcontaining Ak molecules would fail to accumulate in the
endocytic pathway, thus accounting for the lack of effective presentation of the 34-45 determinant in the absence
of Ii. However, confocal immunofluorescence microscopy
unexpectedly revealed the steady state localization of class
II in a variety of endocytic structures, including lamp 1+
compartments, in cells expressing mutant molecules with
either the
tail deletion or
CTAA (data not shown). This
suggested that either a recycling model for presentation of
these determinants was incorrect, or that the loss of presenting function due to these mutations resulted from a
more subtle change in the trafficking of class II than revealed by such staining studies. We therefore examined the
entry of mature surface class II molecules into endosomes using surface-bound antibody as a probe. Cells expressing
wild-type Ak with or without Ii rapidly internalize a substantial fraction of antibody-bound surface class II; within 5 to 10 min of warming to 37°C, distinct staining of small
vesicles is observed and accumulation of signal in larger vesicular structures is readily apparent by 15 to 30 min (Fig. 5).
In contrast, cells expressing Ak containing either the taildeleted or double alanine mutant
chain show little evidence of internalized class II at 10 min and only modest
staining of very small vesicles at 30 min. Cells expressing
class II molecules lacking both the
and
chain cytoplasmic regions show no detectable intracellular class II accumulation using this method at up to 150 min of incubation
(data not shown), suggesting that the residual internalization seen with the
CTAA-wild-type
combination may
depend on a separate, as yet uncharacterized, signal in the
chain tail.
Fig. 5.
Deletion or mutation of the A cytoplasmic tail results in a
delayed rate of internalization of mature surface class II into the endocytic
pathway. RBL stable transfectants expressing A
k along with the indicated A
chains were bound to anti-class II mAbs in the cold, then
warmed to 37°C for the indicated times. Cells were then permeabilized
and stained for mouse immunoglobulin and analyzed by confocal immunofluorescence microscopy.
[View Larger Version of this Image (137K GIF file)]
activated M
fail to present a particular insulin determinant (52), although B cells from the same
mouse are fully competent to do so. This difference appears
to be related to the more rapid and complete digestion of insulin by the M
, which prevents effective capture by class
II. Given the different locations of the three HEL determinants in the native protein, one might expect that 116-129 and perhaps 34-45, but not 46-61, to be overdigested in
activated macrophages, as compared to the B cell blasts
used in the studies shown in Fig. 1. As shown in Fig. 6, this
is the case. IFN-
-activated macrophages are quite effective in presenting the 46-61 determinant, but inefficient in
presenting either the 34-45 or 116-129 determinants. If
chloroquine or leupeptin is added to HEL-exposed macrophages before fixation, there is a paradoxical dose-dependent gain in presentation of the 34-45 and 116-129 determinants, but a decline in the presentation of 46-61.
Fig. 6.
Differential presentation of the three HEL determinants by
IFN--activated macrophages and the effects of inhibitors of protein degradation on this presentation. Peritoneal macrophages were cultured in IFN-
for 48 h, and then exposed to the indicated concentrations of HEL for 6 h
or 50 µM HEL for 6 h with or without the indicated drugs. Cells were
then washed, fixed, and used as APCs for the appropriate T hybridomas. IL-2
production at 24 h is presented as OD obtained using an IL-2-specific capture ELISA. The data represent one of the three independent experiments.
[View Larger Version of this Image (21K GIF file)]
and
chains (54) and GLUT4 (55) that
also promote trafficking of the respective proteins to endocytic organelles. Ii proteolysis and removal is minimal
during passage through early endosomes, modest in late endosomes, and extensive in a lysosome-like fraction (10) that corresponds to the MIIC defined by immunoelectron microscopy (6). Class II molecules cannot bind a new ligand
until Ii is degraded and CLIP is removed or dissociated from
the class II binding site, in large part through the action of
DM that is concentrated in the MIIC by a distinct tyrosinecontaining motif (56). Therefore, Ii-associated, newly synthesized class II molecules are most likely to participate primarily in the presentation of determinants surviving until,
or first exposed in, this highly proteolytic, acidic environment. In accord with this, the 46-61 determinant of HEL,
which is located in the core of this globular protein and
protected by disulfide bonds, shows a strong dependence
on Ii for its presentation. This agrees with studies indicating
that the best presentation of this determinant occurs when
lysosome-like organelles with strong reducing capacity are
accessed by HEL (44, 45) and showing that this peptide has
a pH optimum of 5 for binding to Ak (57).
chains which, when deleted or altered to
GAA, resulted in class II molecules unable to present the
34-45 or 116-129 determinants in the absence of Ii. The
variable effect of mutation at these leucines on presentation
of distinct antigenic determinants is consistent with the earlier suggestion by Smiley et al. (32) that a signal containing
these residues could play a role in differential antigen presentation by tailless versus wild-type class II molecules.
chain whose cytoplasmic tail had been truncated. Because CLIP release is facilitated at acidic pH (61),
decreased internalization due to the
mutation would allow such complexes to accumulate to a higher level on the
plasma membrane, rather than dissociating upon internalization and recycling. The decrease we observed in class II
internalization rate without a loss of steady-state localization in endocytic organelles following mutation of a dileucine signal is also very similar to results obtained in studies
of the GLUT4 glucose transporter (55).
chain tail control the
rate of class II entry into the endocytic pathway for capture of only a subset of antigenic determinants provides an explanation for earlier reports of a variable influence of class II
tail deletion on antigen presentation (29, 30). Our evidence
that a leucine-based motif is involved in this endocytic targeting emphasizes the importance of this motif in immunological function, especially as concerns T cell antigen recognition. On the other hand, the rather modest effect of
elimination of the class II tail motif on in vivo immunity to
a range of pathogens (32) raises some question as to the physiologic significance of this Ii-independent pathway.
However, the organisms studied in this report were primarily those resident in the endocytic compartment itself, and
not viruses, for which we argue the recycling pathway may
have a special importance. It is also the case that the studies
conducted here have not been performed in typical hematopoietic antigen presenting cells. This clearly leaves to
future studies a fuller determination of the roles of the two
class II pathways defined here in the protective functions of
the immune system.
Address correspondence to Ronald N. Germain, Lymphocyte Biology Section, Laboratory of Immunology, NIAID, NIH, Bldg 10, Rm 11N311, 10 Center Drive MSC-1892, Bethesda, MD 20892-1892.
Received for publication 3 October 1996
The authors wish to thank members of the Lymphocyte Biology Section for many helpful discussions and suggestions throughout the course of this work. We also thank Drs. Jack Bennink and Jon Yewdell for their assistance with confocal microscopy, Luciano Adorini for providing critical T hybridomas, and Eric Long, Flora Castellino, and Caetano Reis e Sousa for comments on the manuscript. We also thank an anonymous reviewer for very useful suggestions for improving the original submitted manuscript.1. | Germain, R.N.. 1994. MHC-dependent antigen processing and peptide presentation: providing ligands for T lymphocyte activation. Cell. 76: 287-299 [Medline] . |
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