(Received for publication, August 6, 1996, and in revised form, December 23, 1996)
From the Center for Neurobiology and Psychiatry, University of California, San Francisco, California 94143
Two -galactoside-binding proteins were found
to be prominently expressed in the human colon adenocarcinoma T84 cell
line. Cloning and sequencing of one, a 36-kDa protein, identified it as
the human homolog of galectin-4, a protein containing two carbohydrate binding domains and previously found only in the epithelial cells of
the rat and porcine alimentary tract. The other, a 29-kDa protein, is
galectin-3, containing a single carbohydrate binding domain, previously
found in a number of different cell types including human intestinal
epithelium. Despite the marked similarities in the carbohydrate binding
domains of these two galectins, their cellular distribution patterns
are strikingly different and vary with cellular conditions. In
confluent T84 cells, galectin-4 is mostly cytosolic and concentrated at
the basal membrane, whereas galectin-3 tends to be concentrated in
large granular inclusions mostly at the apical membrane. In
subconfluent T84 cells, each galectin is distributed to specific
domains of lamellipodia, with galectin-4 concentrated in the leading
edge and galectin-3 more proximally. Such different localization of
galectins-4 and -3 within T84 cells implies different targeting
mechanisms, ligands, and functions. The localization of galectin-4
suggests a role in cell adhesion which is also supported by the ability
of immobilized recombinant galectin-4 to stimulate adhesion of T84
cells.
Galectins are a family of animal lectins defined by affinity for
-galactoside-containing saccharides and by shared sequence elements
(for review, see Ref. 1). Previous work has shown that galectin-4 and
galectin-3 are both present at high concentration in intestinal
extracts (2-4). Galectin-4 has only been found in the epithelium of
the alimentary tract, including oral mucosa (5), esophagus (6), and
intestinal mucosa (3), whereas galectin-3 is also abundant in other
cells, especially macrophages (7, 8).
Although galectins are cytosolic proteins lacking signal sequences, galectins-1 and -3 are known to be externalized by nonclassical secretory mechanisms (9-12), suggesting that others, including galectin-4, might also be released from cells in this way. Galectin-1 and galectin-3 have been shown to bind extracellular matrix components (13, 14) and modulate cell adhesion (15, 16). Hence, it is plausible that galectin-4 is also involved in cell adhesion by interacting with extracellular glycoconjugates. No specific ligands for galectin-4 have been identified so far, but its interaction with an adherens junction component in oral mucosa has been indicated (5).
As a step in determining the function of galectin-4, we have examined its localization in the human colonic adenocarcinoma T84 cell line frequently used as a model of intestinal crypt epithelium (17-19) and compared it with the localization of galectin-3. We found that despite the marked similarities in the carbohydrate binding domains of these two galectins, their distribution patterns in the same cells are strikingly different, with galectin-4 localized mainly at sites of cell adhesion.
An 35S-protein labeling mix EXPRE35S35S (>1,000 Ci/mmol) was purchased from DuPont NEN. Sepharose CL-2B was obtained from Pharmacia Biotech Inc., and protein G-Sepharose was obtained from Zymed (South San Francisco, CA). The peroxidase substrate kit was from BioGenex (San Ramon, CA). All other reagents, unless specified, were obtained from Sigma.
AntibodiesA rat monoclonal anti-galectin-3 (anti-Mac-2) (7, 8) was used as described (20). Rabbit anti-galectin-4 serum was raised against the COOH-terminal domain of rat intestinal galectin-4 as described (3). A monoclonal anti-cytokeratin antibody 7D3 was a generous gift from Dr. Caroline Damsky, University of California, San Francisco (21). A mouse monoclonal antibody (IgG2a) against the intracellular domain of human E-cadherin was purchased from Transduction Laboratories (Lexington, KY). Fluorescein-conjugated rabbit anti-rat antibodies, biotinylated sheep anti-rat antibodies, streptavidin-conjugated fluorescein, and streptavidin-conjugated Texas Red were purchased from Amersham Corp. Biotinylated goat anti-rabbit antibodies, Vectastain kit, and Vectashield were from Vector (South San Francisco, CA).
Cell CultureT84 cells (passages 54-70) were grown following the procedure of Dharmsathaphorn et al. (22), in Dulbecco's modified Eagle's H-16/F-12 medium (1:1) containing 5% newborn calf serum, 5% fetal calf serum, penicillin (100 units/ml), streptomycin (100 µg/ml), 15 mM HEPES, pH 7.3, 17.5 mM glucose, and 2.5 mM glutamine, in a humidified atmosphere of 95% air and 5% CO2 at 37 °C (seeding density of 2.5 × 105 cells/cm2). For immunocytochemistry, the cells were grown on uncoated glass coverslips.
Metabolic Labeling and Cell LysisFor labeling in
vivo with [35S]methionine/cysteine, T84 cells were
grown on 10-cm-diameter plastic dishes as described above. Endogenous
methionine/cysteine was depleted before labeling by washing cells with
methionine-free minimal essential medium and incubating in depletion
medium (methionine-free minimal essential medium, 5% dialyzed fetal
calf serum, 10 mM HEPES, pH 7.3) for 1 h at 37 °C.
For labeling, the medium was replaced with 5 ml of the same medium
containing 1 mCi of [35S]methionine/cysteine. After
12 h at 37 °C the cells were washed extensively, first in
prewarmed, then in ice-cold PBS1 (5.4 mM sodium/potassium phosphate, 135 mM NaCl, pH
7.4), and lysed in 1.5 ml/plate of ice-cold lysis buffer: 1 mM EGTA, 1.5 mM MgCl2, 5 mM -mercaptoethanol, 2.5% Triton X-100 (v/v) in PBS, containing protease inhibitors (3 mM phenylmethylsulfonyl
fluoride, 10 µg/ml leupeptin, 10 µg/ml aprotinin). The lysate was
centrifuged at 1,000 × g for 15 min at 4 °C, and
the supernatant was used for purification of galectins by affinity
chromatography.
The
supernatant of the cell lysate was passed over a lactosyl-Sepharose
column (prepared as described by Leffler et al. (2)) equilibrated with the lysis buffer without protease inhibitors. Unbound
material was washed off the column with buffer containing 135 mM NaCl, 20 mM Tris-HCl, pH 7.5, and 5 mM -mercaptoethanol. Lectin was eluted with buffer
containing 150 mM lactose, 50 mM NaCl, and 10 mM Tris-HCl, pH 7.5.
Galectin-3 was immunoprecipitated from
both T84 cell lysate or from galectin-containing fractions eluted from
lactosyl-Sepharose using anti-galectin-3 and protein G-Sepharose as
described (20). All samples were precleared twice with Sepharose CL-2B
before the addition of the primary antibody. The washed precipitates were boiled in SDS-polyacrylamide gel electrophoresis sample buffer and
separated on a 12% polyacrylamide-SDS gel. Proteins were localized by
Coomassie Blue staining followed by fluorography at 70 °C with
Kodak XAR-5 film and intensifying screens.
Protein concentration was measured using the Bio-Rad protein assay. For SDS-polyacrylamide gel electrophoresis the MiniProtean unit (Bio-Rad) was used under standard conditions. The ratio of galectin-3 to galectin-4 was estimated by densitometric scanning.
DNA Cloning, Manipulation, and AnalysisUnless specified otherwise, all manipulations of nucleic acids such as restriction, ligation, transformation, gel electrophoresis, blotting, gel elution, radiolabeling, and preparation of buffers were done using standard protocols (23). Samples were sequenced using Sequenase version 2.0 kit (U. S. Biochemical Corp.). The reported sequence was confirmed on both strands.
Human genomic DNA was amplified with convergent oligonucleotide primer
pairs complementary to several different parts of the rat galectin-4
gene (3), by PCR using 1 µg of human genomic DNA
(CLONTECH)/50-µl reaction. Reactions were carried
out under conditions described by Gitt et al. (24) for 45 cycles: 40 s at 95 °C, 1 min at 55 °C, and 4 min at
72 °C. PCR using primers 5-CTGCCATGGCGGGACCCCCGATCTTCAA-3
and
5
-ATGATGGTTCTTCGGGCTG-3
yielded a major product that was cloned into
the pCR1000 vector (Invitrogen, San Diego) according to the
manufacturer's instructions. This product was a gene fragment
containing an intron flanked by two exon fragments. A human
gene-specific antisense primer (HL36A, 5
-TGAGCCCTCCTTGCAGCC-3
) was
designed based on one of the exon sequences, to be used in PCR of
reverse transcribed RNA.
Total RNA was isolated from confluent T84 cells using RNazol (Tel-Test,
Friendswood, TX) according to the manufacturer's protocol. The RNA was
reverse transcribed, using Moloney murine leukemia virus reverse
transcriptase, with the C35 primer
5-GACTCGAGTCGACATCGATTTTTTTTTTTTTTTTT-3
, which is designed to
hybridize with poly(A) and to provide an anchor sequence for use in
subsequent PCR. The 20-µl solution was then diluted to 1 ml with 10 mM Tris-HCl, pH 7.6, 1 mM EDTA, and 5 µl of
this diluted solution was used in PCR with the antisense primer HL36A
described above, and a sense primer (
1, 5
-TTCTATGAATACGGGCACCGG-3
) designed based on further upstream sequence of rat galectin-4. The PCR
conditions were: 5 cycles of annealing at 50 °C for 1 min and 40 cycles of annealing at 60 °C for 1 min, and extension at 72 °C
was for 2 min in all cycles. One pure band was obtained, cloned into
pCR1000, and sequenced using vector-specific primers. Based on this
sequence, a sense human-specific primer, HL36B, 5
-TACCCTGGTCCCGGACATTG-3
, was synthesized, and PCR was performed with
primers HL36B and C19 (a primer containing the anchor sequence (non-oligo(dT)) of primer C35) and cDNA as template. Annealing was
at 56 °C for 1 min, and polymerization was at 72 °C for 1.5 min.
A single band was obtained and ligated into pCR1000, yielding a clone
that was used as a probe to screen a
ZAP-II cDNA library prepared from T84 cells (a generous gift from Dr. J. R. Riordan, Sick
Children's Hospital, Toronto). Positive clones were purified by
rescreening. One positive clone was found to contain all previously identified sequence and additional 5
sequence. Subsequently a galectin-4 cDNA clone, isolated as an expressed sequence tag (25) from a T84 cell cDNA library (I.M.A.G.E. consortium; clone ID 509819), was obtained (in the Bluescript SK
vector) from Genome Systems Inc. (St. Louis). Sequencing of this clone confirmed the identity with our previously obtained galectin-4 sequences and provided
additional 5
sequence to complete the galectin-4 coding sequence.
Cells grown on uncoated coverslips were washed with PBS and fixed either with 4% paraformaldehyde-periodate-lysine (PLP) (26), or with 4% paraformaldehyde in PBS for 12 h at room temperature, and washed repeatedly with PBS. The cells were permeabilized with 0.025% saponin in PBS for 10 min at 37 °C. Nonspecific antibody binding was blocked by incubation of fixed cells in PBS containing 6.6 mg/ml fish skin gelatin (Sigma), and cells were incubated with primary antibody in PBS-fish skin gelatin for 1 h at room temperature, washed for 10 min three times in PBS-fish skin gelatin, incubated with fluorochrome- or biotin-conjugated secondary antibody in PBS-fish skin gelatin for 30 min, washed, and incubated with streptavidin-conjugated second fluorochrome in PBS for 30 min. Samples were then washed thoroughly in PBS, and after a final rinse in double distilled H2O mounted in Vectashield (Vector Laboratories, Burlingame, CA) and analyzed in a laser scanning confocal module (Bio-Rad MRC600 confocal head attached to a Nikon Optiphot microscope) with a × 63 1.4 N.A. objective, 0.5 s/scan with 12 frames/image, Kalman filter, and 1 µm/step for XY sections; 0.3 µm/step was used for XZ sections.
To remove extracellular Ca2+, the cells were incubated in growth medium containing 4 mM EGTA, pH 7.4, for 15 or 30 min at 37 °C (27), rinsed with Ca2+, Mg2+-free PBS, fixed, and processed as above.
Expression and Purification of Recombinant Rat Galectin-4Escherichia coli producing full-length rat
galectin-4 was generated using the pET system (Novagen, Madison, WI) as
described by Oda et al. (3). The culture, extraction, and
lectin purification were also done as described (3), except for
induction at lower temperature and French press lysis to circumvent the
insolubility of the galectin-4. In brief, 1 liter of Luria broth with
50 mg of ampicillin was inoculated with a 15-ml overnight culture of the galectin-4-expressing E. coli, and then shaken for
3 h at 37 °C. The temperature was lowered to 30 °C,
isopropyl-1-thio--D-galactopyranoside (100 mg) added,
and the incubation continued for another 3 h. The bacteria were
harvested by centrifugation, and the pellet was either frozen or
processed immediately. The bacterial pellet was resuspended in 15 ml of
PBS containing 4 mM
-mercaptoethanol and 2 mM EDTA (ME-PBS), and 1 mM phenylmethylsulfonyl
fluoride on ice and lysed three times with a French press, the lysate
was centrifuged at 100,000 × g for 45 min. The
galectin was purified from the clear supernatant by affinity
chromatography on lactosyl-Sepharose. The yield of active soluble
galectin-4 was about 20 mg per liter of bacterial culture. The galectin
was stored at 4 °C in ME-PBS containing 150 mM lactose.
Before use, an aliquot was chromatographed on a Superdex 75HR column
(Pharmacia) in ME-PBS to remove lactose.
Adhesion of T84 cells to coated wells was examined by procedures described in detail by McClay et al. (28) and Lotz et al. (29). Every other eight-well row in the flexible microtiter assay plate (MicroTest III, Becton Dickinson, Oxnard, CA) was treated with solutions of laminin (5 µg/cm2), BSA (2%) or rat recombinant galectin-4 (5 µg/cm2) in PBS. After the addition of 50 µl to the wells, the plates were covered with Saran Wrap and incubated for 12 h at room temperature. Coated wells were washed for 10 min three times with PBS, and nonspecific adhesion sites were blocked by incubation with 2% BSA in PBS for 2 h at room temperature, followed by three 10-min washes with PBS.
Subconfluent T84 cell cultures were labeled with 10 µCi/ml [35S]methionine/cysteine as above, rinsed quickly with Ca2+- and Mg2+-free PBS, and gently dissociated to single cells and small cell clusters by incubation for 1 min at 37 °C with 0.05% trypsin solution containing 0.02% EDTA, prewarmed to 37 °C. The cells were rinsed once in the growth medium and resuspended in the fresh growth medium to 4 × 104 cells/ml. The viability of cells as assessed by trypan blue exclusion was >99%. 300 µl of cell suspension was added to fill each well, and wells were sealed with an adhesive tape, avoiding formation of air bubbles. The plates were centrifuged at 24.9 × g for 8 min at 4 °C to bring the cells to contact with the substrate ("spin on"); after incubation for 30 min at 37 °C, the plates were inverted and centrifuged at 100 × g, for 8 min at 4 °C, to dislodge the nonadhering cells from the substrate ("spin off"). The plates were then quick-frozen in a dry ice-ethanol mix. The bottom 3 mm of each well was excised, and the adhering cells were quantified by scintillation counting in the presence of scintillation fluid. The total amount of applied cells (100%) was obtained by quantitation of cells remaining at the bottoms of BSA-coated wells immediately after the first centrifugation (spin on).
The same conditions were used to study the inhibition of T84 cell adhesion by various saccharides, except that in this case a 2 × cell suspension (about 8 × 104 cells/ml growth medium) was mixed with medium containing 2 × the final concentration of lactose or cellobiose before 300 µl of the mixture was added to the wells with immobilized galectin-4, laminin, or BSA.
To
study the localization and function of galectins in a cell culture
model of intestinal epithelium, we looked for these lactose-binding
proteins in T84 colon carcinoma cells by affinity chromatography of
cell extracts on lactosyl-Sepharose. We found that T84 cells express
high concentrations of a 36-kDa and a 29-kDa galectin (Fig.
1, lanes A and B). The former
reacted with anti-rat-galectin-4 on Western blots (Fig. 1, lane
C), and the latter was immunoprecipitated by monoclonal
anti-galectin-3 antibodies (Fig. 1, lane D).
The expression of galectin-4 in T84 cells was confirmed by cDNA
cloning and sequencing (Fig. 2a). The amino
acid sequence of the encoded T84 cell protein showed about 80%
sequence identity with rat and porcine galectin-4 within the
carbohydrate binding domains and about 50% sequence identity within
the link region, and it contained all residues that are typically
conserved in galectins and known to be associated with carbohydrate
binding activity (Fig. 2b). From these data we conclude that
the 36-kDa lactose-binding protein of T84 cells is human
galectin-4.
Recently, sequences of a large number of randomly picked cDNA clones (expressed sequence tags) (25) from a T84 cell cDNA library have become publicly available. A search of these revealed that out of about 9,000 available sequences, 23 correspond to galectin-4, and 8 correspond to galectin-3, but no sequence corresponds to any other galectin. This provides further evidence that galectin-3 and galectin-4 are the main, or maybe sole, galectins expressed by T84 cells.
High Level of Expression of Galectins-4 and -3 in T84 CellsThe relative combined amount of galectin-3 and -4 in T84 cells was estimated as the amount of [35S]methionine/cysteine incorporated in the galectins compared with total trichloroacetic acid-preciptable protein from 2.5% Triton X-100 cell lysates. The combined radioactivity incorporated into the two galectins represents 1.4% of the tricholoracetic acid-precipitated radioactivity in early confluent cells but declined to about 0.5% in aging cells. Densitometry of SDS-polyacrylamide gel electrophoresis of the purified galectin mixture showed that galectin-4 accounts for 38-60% of the total galectin content.
The molar concentration of the galectins in T84 cells was calculated
based on the absolute yield of lactosyl-Sepharose-purified galectins
from a given area of confluent monolayer. Thus, about 0.5 mg of
galectin was obtained from 10 culture plates (10-cm diameter),
corresponding to a cell monolayer area of 800 cm2. Since
the cells are on average 25 µm high (Fig. 3), this
corresponds to a cell volume of 2 ml. Hence the combined concentration
of the galectins is 0.25 mg/ml or about 8 µM. Based on
the relative amounts of each galectin estimated by densitometry, the
average concentration of galectin-3 and -4 in T84 cells is about 5 and 3 µM, respectively.
Conditions for Immunocytochemistry of Galectins
The
distribution of the two galectins in T84 cells was examined by
immunocytochemistry and confocal microscopy. However, the immunocytochemical detection of the galectins was complicated by an
unexpected difficulty in galectin fixation. Application of standard
fixation and permeabilization conditions resulted in very weak staining
of both galectins, suggesting that the galectins, which are very
abundant in T84 cells, were lost because of poor fixation. Indeed, both
galectins were found in the solutions used for cell permeabilization
and could be purified on lactosyl-Sepharose, showing that they retain
activity. It was particularly notable that active galectins could be
identified that way even in methanol and acetone solutions (lyophilized
and resolubilized in lysis buffer) collected after cell "fixation"
for 5 min at 20 °C. Therefore, several permutations of different
fixation and permeabilization procedures were tested which included
prolonged fixation (12 h with 4% PLP or with 4% paraformaldehyde)
followed by mild brief permeabilization with either saponin (0.025% in
PBS, 10 min) to visualize intracellular galectins in confluent cells,
or standard PLP-fixation without permeabilization to visualize
membrane-associated galectins in EGTA-treated confluent and in
subconfluent cells.
Fig. 3a presents the localization of
galectin-4 (red) and galectin-3 (green) in
25-µm-tall confluent T84 cells as XZ sections after prolonged PLP
fixation and brief saponin permeabilization. Galectin-4 is seen mainly
as a 1-2-µm-thick layer near the basal membrane. Galectin-3 is
mainly found in subapical accumulations revealed more clearly after
fixation with paraformaldehyde instead of PLP (Fig. 3b). XY
sections confirmed the apical-basal polarity of galectin distribution
and also revealed significant amounts of diffusely distributed
galectins (Fig. 4). Thus, panel a of Fig. 4
recorded at the level of the apical membrane (26 µm above the
substratum) shows mainly galectin-3, whereas panel c
recorded 1 µm above the substratum shows mainly galectin-4.
The XY sections also revealed particularly dense accumulations of the two galectins with a distinct morphology at the apical membrane (Fig. 4a, arrowheads), which were not seen readily in the XZ sections. Higher magnification of these detergent-resistant apical accumulations of galectins (Fig. 4d) demonstrates their very defined shape and composition. Galectin-4 is concentrated into circular accumulations with a large adjacent zone of galectin-3 either in the cell center (large arrowhead) or at the site of cell-cell contacts (small arrowhead) at the apical membrane (Fig. 4d). There is usually one organized accumulation of galectins in each confluent cell, and such formations have not been found in nonconfluent cells.
Immunocytochemical Localization of Galectin-4 in Confluent Calcium-depleted T84 MonolayersThe galectin-4 localization at the adherens junctions in porcine tongue squamous epithelium (5, 30) was not observed in the permeabilized confluent T84 monolayers. Since this might be due to the difficulties of fixing galectin-4 to its neighboring proteins resulting in its loss from permeabilized cells, as discussed above, we used an alternative approach to look for lateral localization of galectin-4 without permeabilization. To gain access to the extracellular adherens junction area in confluent T84 cells without permeabilization, the tight junction complexes were uncoupled by brief removal of Ca2+ with EGTA followed by fixation with PLP.
These EGTA-treated confluent monolayers were double immunolabeled for
galectin-4 (red), and cytokeratin (green, Fig.
5). Cytokeratin immunostaining was used here as an
indicator of the ability of antibodies to gain access to the interior
of nonpermeabilized T84 cells; indeed, the anti-cytokeratin antibodies
stained a layer about 2 µm inside the cell perimeter, outlining each
cell, indicating that antibodies can penetrate nonpermeabilized T84
cells.
In the cells treated with EGTA for 15 min, galectin-4 is mainly observed as dramatic red patches (Fig. 5a, arrowhead) covering a large (8-16-µm long) lateral membrane area of cells next to a site of breakage in the monolayer. Following removal of Ca2+ with EGTA for 30 min (Fig. 5b), cell shapes were much less regular, and there were many more patches of galectin-4 covering the lateral membranes (Fig. 5b, arrowheads), again mostly next to a site of breakage in the monolayer. There was little if any colocalization of cytokeratin with galectin-4. Instead, in these conditions galectin-4 seemed to be localized more toward the cell periphery than cytokeratin, or extracellularly. These characteristic lateral galectin-4 patches were never seen in confluent monolayers that had not been treated with EGTA, but they persisted upon permeabilization.
Since in porcine oral squamous epithelium galectin-4 colocalizes with
E-cadherin (5), we compared the localization of galectin-4 (red) and the intracellular domain of E-cadherin
(green; Fig. 6, a-d) in
EGTA-treated confluent T84 cells. After 30 min of EGTA treatment, the
main galectin-4 staining was found near the apical membrane (XY plane
24 µm above glass level; Fig. 6a), concentrated in
brightly staining crescent-shaped aggregations. These crescents are
found at sites of the characteristic apical rounding and separation from neighboring cells and correspond to the lateral galectin-4 patches
shown in Fig. 5, a and b. Less intense galectin-4
staining was found in the form of similar crescents 8 and 16 µm below
the apical membrane, where most E-cadherin was found in the form of intracellular vesicular staining that did not colocalize with galectin-4 (Fig. 6, b and c,
arrowheads).
It is notable that the galectin-4 staining seen near the basal membrane and diffusely cytosolic in permeabilized cells not treated with EGTA (Figs. 3 and 4) was diminished after a 15-min EGTA treatment (Fig. 5a) and not seen in the cells treated for 30 min with EGTA even if the anti-cytokeratin and anti-E-cadherin clearly had access to these sites. In addition, this basal and cytosolic staining was also absent in EGTA-treated and saponin-permeabilized cells (not shown), whereas the lateral galectin-4 patches were present as mentioned above. Hence, it is possible that detergent-resistant galectin-4-rich patches at the lateral membrane are the result of an EGTA-induced accumulation of galectin-4 at this site. Alternatively, galectin-4 at this site is exposed when cell-cell junctions are broken, and the galectin-4 at other sites is lost through independent mechanisms. Fig. 6 shows that some galectin-4 colocalizes with E-cadherin remaining at the lateral site typical of adherens junctions, but not with most of the E-cadherin that appears to have been internalized after calcium depletion (as observed in Madin-Darby bovine kidney cells) (27).
Galectin Distribution in Subconfluent T84 CellsThe distribution of galectin-4 and galectin-3 in T84 cell cultures at different stages after seeding was examined by immunocytochemistry of fixed but not permeabilized cells. For these experiments, 2-3-day-old subconfluent cells were dissociated by brief and mild trypsin (0.05%) and low EDTA (0.02%) treatment for 1 min at 37 °C. These brief and gentle conditions were chosen since dissociation with a higher concentration of EDTA or EGTA results in a decreased rate of cell attachment and great loss of observable galectin-4. The cells were examined at 2, 12, 24, and 48 h after seeding.
An XZ section through a typical cell cluster 2 h after seeding is
shown in Fig. 7a. In this cluster two cells
are attaching to the substrate, and the top cell has not yet attached.
A horizontal optical section through the top cell (Fig. 7b)
shows a remarkable concentration of galectin-4 within one hemisphere of
the cell periphery, whereas galectin-3 is distributed evenly around the cell periphery. This pattern was typical for rounded and not yet attaching cells. It is possible that this polarization of galectin-4 reflects the organization of the periphery of basal and apical cytoplasm (compare with Figs. 3 and 4) retained by the cells after dissociation from the polarized monolayer.
In the two attached cells seen at the bottom of the cluster in Fig. 7a, galectin-4 is concentrated at the points of cell-substrate contact (arrowheads), whereas galectin-3 is found along a large part of the cell membrane. In 12-h- and 24-h-old colonies (Fig. 7, c and d), galectin-4 is again concentrated to small areas of the cell periphery at the same pole of pairs of newly divided cells (Fig. 7c) and at newly formed substrate contact sites at the colony periphery (Fig. 7d, small arrowhead). In contrast, galectin-3 is distributed more diffusely in the peripheral cytoplasm, including the vicinity of the membrane separating the newly divided cells. The galectin-4-positive patches that are often noticed at the surface of the glass (large arrowhead in Fig. 7d) are probably the remnants of attachment sites of cells dislodged during washes. The thin red line seen at the level of the glass in areas not covered by cells (Fig. 7a) may also be the result of adsorbed galectin-4 released from disrupted cells.
In 48-h cultures, large colonies have formed with cells rapidly
proliferating and establishing first contacts with the substrate at the
edge and more differentiated cells in the interior. Fig. 8 shows an overview of the galectin localization in such
cultures revealed with immunoperoxidase instead of immunofluorescence
to permit covisualization of the underlying cell and colony morphology. It is clear that both galectin-3 (panels a and c)
and galectin-4 (panels b and d) are found in most
lamellipodia at the edge of these fixed but not permeabilized cell
colonies. In saponin- or methanol-permeabilized subconfluent cells,
both galectins are essentially absent from lamellipodia (not shown),
suggesting that their association with other cellular components at
this location is detergent-sensitive in contrast to the galectin-4 seen
at the lateral membrane of calcium-depleted cells shown in Fig. 5,
a and b.
Double immunostaining and confocal microscopy of the 48-h cultures showed that both galectins are found within the same lamellipodia but in clearly distinct regions (Fig. 7, e and f); galectin-4 is always concentrated in the leading edge, whereas galectin-3 is found distributed more diffusely in the more proximal part. This distribution is preserved both in the compact, pointed lamellipodia typical for serum-starved cells (Fig. 7e) and in the wide flat (1-2-µm-tall, Fig. 7f, inset) but delicate and webby outgrowth areas seen 15 min after serum stimulation. Hence, the distribution of galectins defines three areas of lamellipodia: a leading edge occupied exclusively by galectin-4, the central area where the two galectins colocalize, and a proximal region rich in galectin-3.
In conclusion, in subconfluent T84 cells, galectin-4 is found in attachment sites of newly seeded cells and at the leading edge of lamellipodia. In contrast, galectin-3 is distributed along most of the cell periphery of these cells and is more concentrated in the posterior part of lamellipodia. Nuclear accumulation of galectin-3, observed previously in proliferating 3T3 cells (31) and normal colon epithelial cells (32), was not observed in T84 cells; in this regard T84 cells resemble other colon carcinoma cells (32).
Rat Recombinant Galectin-4 Enhances Adhesion of T84 CellsSpecific accumulation of galectin-4 in the cell-substrate contact sites in attaching cells, in lamellipodia of growing cells, and at the basal membrane of confluent monolayers suggests its involvement in cell-substrate adhesion. As the first attempt to investigate this possibility, we tested the ability of surface-adsorbed rat recombinant galectin-4 to support adhesion of T84 cells, using the procedure of McClay et al. (28).
The subconfluent T84 monolayers were dissociated to single cells and
small cell clusters (such as shown in Fig. 7a) and brought into contact with microtiter wells coated with rat recombinant galectin-4, laminin, or BSA. After a 30-min incubation at 37 °C followed by centrifugation of the inverted microtiter plates at 100 × g for 8 min at 4 °C, about 19% of all cells
remained attach to galectin-4, compared with less than 1% of cells
bound to BSA, and 65% cells attached to laminin (Fig.
9A). Hence, galectin-4 supports significant
T84 cell adhesion, implying that it interacts with one or more
receptors at the T84 cell surface.
The adhesion of cells to immobilized galectin-4 could be inhibited by
lactose in a dose-dependent manner with 2.5 mM
giving about half-maximal inhibition (Fig. 9B). Cellobiose
was used as a control because it differs from lactose only by the
stereochemistry of the 4-OH (axial in lactose, equatorial in
cellobiose) but does not bind galectins (1, 33). Cellobiose was at
least 100-fold less potent as an inhibitor of T84 cell binding to
galectin-4. The binding of T84 cells to laminin was inhibited 10% by
25 mM lactose and not at all by 25 mM
cellobiose. This shows that the cells were sufficiently intact to
adhere and not affected deleteriously by nonspecific effects of these
saccharide concentrations.
This paper describes the different locations of two very abundant galectins, galectin-3 and -4, in T84 cells in the subconfluent state and after differentiation into a polarized epithelium. In confluent polarized cells the two galectins accumulate at opposite poles, with galectin-3 at the apical and galectin-4 at the basal membrane. In subconfluent cells they concentrate in different parts of lamellipodia, with an accumulation of galectin-4 at the leading edge and galectin-3 localized more proximally.
Concentration of these galectins in defined subcellular areas has been observed earlier both in cultured cells and in tissues. Apical localization of galectin-3 in T84 cells agrees well with the similar finding in other polarizing epithelial cell lines (10, 11) and in kidney epithelium (34). Galectin-4 has been found previously in globular structures at the cell periphery corresponding to areas of adherens junctions in oral epithelium (5) and in aggregates at the apical membrane of lumenal cells in esophageal epithelium (6).
The natural ligands for galectins are thought to be -galactosides,
and the differences in their binding specificity for complex saccharides (2, 3, 33) would be sufficient to explain differential
targeting. However, since
-galactosides are not detectable in the
cytoplasm, the intracellular galectin ligands must be of another
nature, probably proteins. Indeed, interaction between galectin-3 and a
nuclear glucose-binding protein of 70 kDa (CBP70) has been demonstrated
(35), and most recently galectin-3 was shown to associate with
Bcl-2, a well known intracellular suppressor of apoptosis
(36). Both of these associations occur via protein-protein interactions
but are inhibited by lactose, indicating direct or indirect involvement
of the galectin carbohydrate binding site. The association of
galectin-3 with cytoplasmic and nuclear ribonucleoprotein complexes
reported by Wang et al. (37) is not inhibited by lactose,
indicating involvement of another site. To date, there is no
information about intracellular ligands for galectin-4.
Two observations made during immunocytochemistry experiments suggest that one component of cellular galectin complexes might be a lipid. First, detergent treatment of PLP-fixed cells removed the galectins from many locations, suggesting that they were associated with readily extractable components, such as lipids. Second, the galectins remained soluble and active after exposure to methanol, an unusual property among proteins, indicating a remarkable stability in interactions with a hydrophobic environment.
The nature of the large apical saponin-resistant accumulations of galectins (Fig. 4d) and their functional relationship to cellular activity are unknown. These accumulations, which are less than 1 µm thick and between 2 and 10 µm in diameter, are present at or beneath the apical surface of 40-80% of confluent T84 cells, either intra- or extracellularly. It is tempting to speculate that these galectin accumulations would create a specific microenvironment and thus influence biophysical properties of the cytoplasmic membrane. One functional consequence of such accumulations could be structural, by creating conditions to stabilize and reinforce the epithelial cell membranes designed to function under constant mechanical stress. This observation agrees with the proposed role of galectin-4 in stabilizing the apical (lumenal) membranes in rat esophageal epithelium (6).
Our attempts to localize galectin-4 in adherens junctions of T84 cells were unsuccessful. Highly concentrated galectin-4 was visible at the lateral membrane in the form of large patches only after removal of Ca2+ with EGTA (Fig. 5) and only at the membranes of cells surrounding breaks in the monolayer, whereas in these conditions, double immunostaining showed a more even distribution of cytokeratin and the intracellular domain of E-cadherin in every cell. It remains to be determined if galectin-4 is translocated to lateral membrane sites as a result of Ca2+-depletion, or if, instead, some proteins are removed in the process of monolayer dissociation, unmasking galectin-4 already present there. Even if galectin-4 is translocated to, or exposed at the lateral membrane only under certain conditions, it may still play a role in the physiological regulation of monolayer integrity.
The accumulation of galectin-4 at the basal membrane of confluent T84 cells, in the leading edge of lamellipodia in subconfluent T84 cells, and at cell-substrate contact sites in freshly seeded cells suggests a function in cell-substrate interactions. This view is supported further by the following. 1) The two tandem carbohydrate binding domains of galectin-4 (Fig. 2) should enable it to cross-link glycoconjugates at the cell surface and/or in the extracellular matrix. 2) Galectin-4 is externalized at the basolateral surface of polarized cells including T84 (38). 3) Surface-adsorbed recombinant galectin-4 induces adhesion of T84 cells (Fig. 9) in a lactose-sensitive way.
The limited effect of lactose on binding of T84 cells to laminin (a common measure of cell-substratum adhesion) does not rule out a role for galectin-4 in cell adhesion. Its role may be in an earlier stage or a different aspect of the complex cell adhesion process than is measured by this assay. For example, the sharply demarcated galectin-4 accumulations observed at the sites of breaks in the monolayer after Ca2+ depletion and at the tips of lamellipodia invites the speculation that it helps in initial reattachment and/or spreading of cells in a disrupted cell monolayer. Morphologically similar lamellipodia-like extensions and localized lateral membrane changes form quickly around the edges of a wound, either experimentally induced in a T84 monolayer (39) or in vivo during restitution of the intestinal epithelium (40, 41). In this way, galectin-4 could play an important role in the maintenance of epithelial integrity and in the epithelial wound healing process.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U82953[GenBank].
We thank Drs. Olga Genbacev-Krtolica for help with microscopy and creative discussions, Michael Silver for an introduction to confocal microscopy, Akraporn Prakobphol for help with the cell adhesion assay, and Susanne Crawley for a critical reading of the manuscript.