Originally published In Press as doi:10.1074/jbc.M202731200 on May 21, 2002
J. Biol. Chem., Vol. 277, Issue 31, 28200-28211, August 2, 2002
Dynamic Change of Neural Cell Adhesion Molecule Polysialylation
on Human Neuroblastoma (IMR-32) and Rat Pheochromocytoma (PC-12) Cells
during Growth and Differentiation*
Geetha L.
Poongodi,
Nimmagadda
Suresh,
Subash C. B.
Gopinath,
Tschining
Chang,
Sadako
Inoue, and
Yasuo
Inoue
From the Institute of Biological Chemistry, Academia Sinica,
Taipei 115-29, Taiwan
Received for publication, March 21, 2002, and in revised form, May 21, 2002
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ABSTRACT |
Polysialic acid (PSA) is a regulatory epitope of
neural cell adhesion molecule (NCAM) in homophilic adhesion of neural
cells mediated by NCAM, is also known to be re-expressed in several human tumors, thus serves as an oncodevelopmental antigen. In this
study, using a recently developed ultrasensitive chemical method in
addition to immunochemical methods, growth stage-dependent and retinoic acid (RA)-induced differentiation-dependent
changes of PSA expression in human neuroblastoma (IMR-32) and rat
pheochromocytoma (PC-12) cells were analyzed both qualitatively and
quantitatively. Both IMR-32 and PC-12 cells expressed PSA on NCAM, and
the level of PSA expressed per unit weight of cells increased with
post-inoculation incubation time. The most prominent feature was seen
at the full confluence stage. RA induced neuronal differentiation in
both IMR-32 and CP-12 cells that paralleled the change in the PSA
level. Chemical analysis revealed the presence of NCAM glycoforms
differing in the degree of polymerization (DP) of oligo/polysialyl
chains, whose DP was smaller than 40. DP distribution of PSA was
different between the cell lines and was changed by the growth stage
and the RA treatment. Thus DP analysis of PSA is important in
understanding both mechanism and biological significance of its
regulated expression.
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INTRODUCTION |
Sialic acid (Sia)1
residues are found in monomeric form almost exclusively at the
non-reducing ends of various glycan chains and also occur in polymeric
forms (PSA) in nature less frequently, less abundantly, and less
diversely than the monomeric residues (e.g. Ref. 1).
2
8-Linked poly(Neu5Ac) on neural cell adhesion molecule (NCAM) is
a universal feature of vertebrates and is known to be developmentally
regulated. NCAM glycoforms having PSA with higher DP are more abundant
in the fetal brain of vertebrates, whereas the majority of NCAM in
adult does not contain PSA. High-DP PSA is considered to be involved in
developmental regulation of homophilic neural cell adhesion and
migration during maturation of embryonic brain (2). High-DP PSA-NCAM is
also known to be re-expressed in certain types of tumors, and thus PSA
chains with high DP are referred to as an oncofetal or
oncodevelopmental antigen (3).
In our recent studies (4-9), we have developed an ultrasensitive and
selective method (DMB/HPLC-FD) for determination of the length or DP of
PSA chains expressed on NCAM at various developmental stages of
embryonic chicken brain (7). We found that DP of PSA chains on NCAM is
indeed mostly 
40 (7-9) and not >55 (or even >100) as estimated
previously (10) for PSA-glycopeptides from human neuroblastoma cells.
Furthermore, our previous results (7) supported the view that there
exist numerous NCAM glycoforms differing in their DP of PSA chains. The
presence of these PSA chains may be necessary for coarse and
fine-tuning of the homophilic binding property of NCAM, and both the
post-translational biosynthesis of PSA and the secretion of these
various NCAM glycoforms are probably physiologically regulated. We
therefore proposed that precise evaluation of PSA chain length may be
the first step for understanding the action of each individual
glycoform associated with a variety of cell-cell interactions, and this
will ultimately control its biological function (7).
In this study we examined the expression of PSA and NCAM in several
cell lines, including human neuroblastoma (IMR-32), human neuroblastoma
from metastatic site of bone marrow (SK-N-SH), human neuroblastoma from
metastatic site of supra-orbital area (SK-N-MC), mouse neuroblastoma
(neuro-2A), and rat pheochromocytoma (PC-12), and we have evaluated PSA
chains expressed in IMR-32 and PC-12 cells by both the DMB/HPLC-FD and
immunochemical methods. It is known that agents such as retinoic acid
(RA) can induce neuroblastoma to differentiate into mature cells with
respect to their metabolism of certain integral biomolecules (11, 12).
We have therefore examined the effect of RA on the expression of PSA as
well as on the morphological changes in IMR-32 and PC-12.
One central question in glycobiology is the role of carbohydrates in
modulating the functions of proteins. The possible presence of a large
number of NCAM glycoforms differing in the DP of PSA chains may be
expected to present an excellent model system to investigate "coarse
and fine-tuning" of the adhesive behavior of NCAM (7). Earlier
immunochemical studies showed that polysialylation in NCAM is
dynamically regulated. Recently, changes in mRNA expression levels
of polysialyltransferases, ST8SiaII and ST8SiaIV, have been correlated
to neuronal differentiation (13). This report represents the first
qualitative and quantitative analysis of PSA expression during neuronal
differentiation of PSA-positive cell lines (IMR-32 and PC-12). These
have proven to be good in vitro models for studying how
changes in the PSA expression would result in fine-tuning of
NCAM-mediated cell-cell association.
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EXPERIMENTAL PROCEDURES |
Antibodies Used--
Rat anti-mouse embryonic PSA-NCAM (CD56)
mAb (12F8, IgM) was purchased from BD PharMingen. Anti-human NCAM mAb
(VIN-IS-53, IgG) developed by P. W. Andrews, and anti-rat NCAM mAb
(5B8, IgG), developed by T. M. Jessell and J. Dodd, were obtained
from the Developmental Studies Hybridoma Bank developed under the
auspices of the NICHD, National Institutes of Health, and maintained by the University of Iowa, Department of Biological Sciences, Iowa City, IA).
Cell Lines and Their Culture and Harvest--
We used the
following cell lines to examine the expression of PSA on NCAM: human
neuroblastoma (IMR-32), human neuroblastoma from metastatic site of
bone marrow (SK-N-SH), human neuroblastoma from metastatic site of
supra-orbital area (SK-N-MC), mouse neuroblastoma (neuro-2A), and rat
pheochromocytoma (PC-12). All of these cell lines were obtained from
the American Type Culture Collection (ATCC) and were purchased from
Food Industry Research and Development Institute, Hsinchu, Taiwan. Each
cell line was cultured in minimal essential medium containing 0.1 mM non-essential amino acids supplemented with 10% fetal
bovine serum (heat-inactivated) and kept at 37 °C in a humidified
atmosphere containing 5% CO2. The cells were transferred
upon reaching confluence, and those within 5 passages after obtaining
from ATCC were used for analysis. For analysis, IMR-32 and PC-12 cells
were harvested by pipetting with phosphate-buffered saline as they
poorly adhered to the surface. Other cells were harvested by
trypsinization. The cells were collected by centrifugation at 1,000 rpm
for 5 min. To examine the growth stage-dependent changes of
polysialylation, IMR-32 and PC-12 cells were inoculated at the
concentration of 5 × 105/ml and were collected
at different stages after inoculation and incubation (24, 36, 48, 60, 72 h, and full confluence). For PSA analyses, the same amounts of
the cells (100 mg wet weight) were processed by exactly the same
procedures to allow direct comparison of the analytical data. The cells
at each stage were examined for their morphological features under a
phase-contrast microscope (Olympus, IX70, Olympus, Tokyo).
Induction of Differentiation with Retinoic
Acid--
All-trans-retinoic acid (RA; Sigma) was dissolved
in absolute ethanol as a stock solution of 10 mM that was
kept in the dark at 
20 °C and used by diluting in medium to a
final concentration of 10 µM. Cells were inoculated,
cultured, and harvested as described above and were used for analysis.
The cells at different stages of development were examined for
morphological changes under a phase-contrast microscope.
Processing of Cells for the Analysis of PSA and Total
Glycoprotein-bound Neu5Ac--
Methods were similar to those described
previously (9). In brief, cells (100 mg, wet weight) were homogenized
in a Polytron homogenizer (Kinematica, Litan, Switzerland) in 600 µl
of chloroform, methanol, 0.01 M Tris-HCl (pH 8.0) mixture
(4:8:3, v/v/v). The residue collected by centrifugation was finally
washed with cold 80% ethanol. Glycosylated and non-glycosylated
proteins were solubilized by sonication and incubation at 37 °C for
0.5-1 h with 100 µl of 0.5% Triton X-100. The insoluble material
was removed by centrifugation, and the supernatant was used for
analysis. The cells with and without RA treatment were analyzed using
the same procedure.
Analysis of PSA and Total Neu5Ac in the Solubilized
Glycoproteins--
PSA and total Neu5Ac in the glycoproteins
solubilized with Triton X-100 were analyzed by HPLC-FD after
derivatization with DMB ((Neu5Ac)N-Q, DMB-tagged
28-linked poly(Neu5Ac) with DP N that is obtained by reacting
(Neu5Ac)N+1 with DMB, where Q denotes fluorescent
chromophore, quinoxalinone derivative)) (7-9). The DMB reagent
contained 5.4 mM DMB (Dojinbo, Kumamoto, Japan), 18 mM sodium hydrosulfite, 1 M
-mercaptoethanol, and 40 mM trifluoroacetic acid. For
PSA analysis, a 40-µl portion of the solubilized fraction was mixed
with 40 µl of the DMB reagent. The mixture was incubated for 48 h at 10 °C. After the reaction, 20 µl of 1 M NaOH was
added to the ice-cold reaction mixture to hydrolyze lactones formed
during incubation under acidic conditions. The alkalinized reaction
mixture was left for 30 min at room temperature and centrifuged, and an
80-µl portion of the supernatant was injected on a DNAPac PA-100
column (Dionex, Sunnyvale, CA). The elution condition was described
previously (7-9). Peaks of oligo/poly(Sia) were monitored with a
fluorescence detector set at 372 nm for excitation and 456 nm for
emission. Because each PSA can acquire only one DMB molecule, the total
peak area for DMB-oligo/poly(Sia) peaks (DP >4) represents the total
number of PSA chains and used as a value comparing the level of PSA in
the cells.
ELISA was performed as a method to evaluate quantitatively the level of
PSA in the cells. A 50-µl portion of the solubilized membrane-bound
glycoprotein was dried in a well of a 96-well plastic plate and
subjected to ELISA using mAb 12F8 and alkaline phosphatase-conjugated goat anti-rat IgM, as the primary and secondary antibody, respectively. The absorbance at 405 nm (p-nitrophenol) of the reaction
mixture represents the amount of PSA epitope.
For total glycoprotein-bound Neu5Ac analysis, a 4-µl portion of the
solubilized samples from delipidated cell-extracts was hydrolyzed in 80 µl of 0.1 M trifluoroacetic acid for 4 h at
80 °C. The acid was removed by evaporation under reduced pressure, and the residue was derivatized with the DMB reagent. DMB-Neu5Ac was
quantified by reverse-phase HPLC analysis as described previously (6,
14).
SDS-PAGE and Western Blot--
Cell pellets (50-100 mg) were
extracted with 200 µl of 1% Triton X-100 containing the following
protease inhibitors: 0.3 units/ml aprotinin, 1 mM
phenylmethylsulfonyl fluoride, 40 µM leupeptin (all
obtained from Sigma). After incubation for 10 min on ice the mixture
was centrifuged at 1000 × g at 4 °C for 5 min. The pellet was re-extracted as above and centrifuged. Protein concentration in the combined supernatant was determined using the BCA reagent (Pierce), and bovine serum albumin as a standard. In SDS-PAGE (gradient
polyacrylamide gel, 4-12%) the running buffer contained 50 mM MOPS, 50 mM Tris-HCl, 3.5 mM
SDS, and 1 mM EDTA (pH 7.7). The gel was run at a constant
voltage of 200 V for 50 min. Cell extracts containing 20 µg of
protein were mixed with 0.25 volume of the buffer (4× LDS sample
buffer, Invitrogen NP0007 46-5030) to obtain a final concentration of
0.29 M sucrose, 0.25 M Tris-HCl, 69 mM SDS, 0.5 mM EDTA, 0.22 mM Serva
Blue G250, and 0.17 mM phenol red and then heated at
70 °C for 10 min. The proteins resolved on polyacrylamide gels were
transferred to polyvinylidene difluoride membrane (15), using a
semi-dry blotting apparatus. For immunoblotting, the membrane was
blocked with 1% skim milk and 0.1% Tween 20 in TBS (TBS, 0.15 M NaCl containing 10 mM Tris-HCl (pH 8.0)) for 1 h at room temperature and incubated with monoclonal antibodies (1-1.5 µg/ml) for 18 h at 4 °C. The secondary antibodies
were used at 0.5-1.5 µg/ml: alkaline phosphatase-conjugated,
affinity-purified goat anti-mouse IgG + IgM (H + L) (Pierce), and goat
anti-rat IgM (µ chain specific) (Southern Biotechnology Associates,
Inc., Birmingham, AL). Color was developed using nitroblue tetrazolium chloride/5-bromo-4-chloro-3-indolyl phosphate p-toluidine
salt (Invitrogen).
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RESULTS |
Diagnostic Examination for the PSA and NCAM Expression in Various
Cell Lines of Neuronal Origin--
The amount of Neu5Ac and the
expression of PSA and NCAM in the solubilized glycoproteins were
analyzed for 3 human and 1 mouse neuroblastoma cell lines and a rat
pheochromocytoma cell line, all harvested at full confluence stages.
The results summarized in Table I
demonstrate that two methods (chemical and immunochemical) led to the
same conclusion that IMR-32 and PC-12 express PSA. These results are
partly in conflict with the previous report (21) showing the absence of
PSA in NCAM-positive wild type PC-12. Both of these cell lines were
NCAM-positive, and immunostaining of the gel after SDS-PAGE using
either anti-PSA or anti-NCAM antibody showed a similar pattern
indicating that PSA was expressed on NCAM. It is noted that mAb
VIN-IS-53 is strictly specific for human NCAM polypeptide sequence. It
is also noted that the values of total glycoprotein-bound Neu5Ac
determined by the present method showed 1 order of magnitude higher
level in PSA-positive IMR-32 and PC-12 compared with PSA-negative
cells, indicating that we can estimate the possible presence of PSA and
evaluate its level from these values.
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Table I
Diagnosis for PSA and NCAM in four different neuroblastoma cell lines
(IMR-32, SK-N-MC, SK-N-SH, and Neuro-2A) and pheochromocytoma cell line
(PC-12) by DMB/HPLC-FD and by Western blot analysis using anti-PSA mAb
(12F8) and anti-NCAM mAbs (5B8 and VIN-IS-53), together with the data
for the amount of glycoprotein-bound Neu5Ac
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Expression and Change in the Level of Polysialylated NCAM in IMR-32
and PC-12 Cells at Different Growth Stages as Revealed by
Immunoreactivity against Anti-PSA mAb (12F8)--
NCAMs in IMR-32 and
PC-12 cells were characterized by Western blot analysis using
monoclonal antibodies, 12F8 and 5B8. The mAb 12F8 recognizes the PSA
portion of polysialylated NCAM, and mAb 5B8 reacts with the
polypeptide portion common to three major isoforms with molecular
masses of 180, 140, and 120 kDa (16). In both IMR-32 and CP-12 cells
relatively narrow smears immunostained with anti-PSA centered at about
150,000 were seen (Fig. 1, A
and B). Immunostaining with anti-NCAM showed similar
patterns indicating that PSA was exclusively expressed on NCAM (data
not shown). The results also indicated that the 140-kDa NCAM was the
major isoform in these cells. Immunostained smears obtained at each
culture time showed that in both cell lines the expression level of PSA was small during the initial 24 h and increased with growth stage between 36 and 84 h when the cells attained confluence. It is noted that in PC-12 the smears are larger than in IMR-32 cells, suggesting the level of PSA-NCAM is higher in PC-12 than in IMR-32 (see
below).
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Fig. 1.
Western blot analysis of the changes in PSA
expression, using anti-PSA antibody in IMR-32 (A) and
PC-12 cells (B) during cell culture for 24 (lane
a), 36 (lane b), 48 (lane
c), 60 (lane d), 72 (lane
e), and 84 h (lane f) (full
confluence). A detergent extract from the cells at each stage (10 µg of protein) was subjected to SDS-PAGE, blotted on polyvinylidene
difluoride membrane, and immunostained with the anti-PSA mAb, 12F8
(CD56).
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Analysis of PSA Expression in IMR-32 and PC-12 Cells at Different
Growth Stages by the DMB/HPLC-FD Method--
We have
established recently a highly sensitive and reliable method of PSA
analysis (DMB/HPLC-FD). The outstanding feature of the method is in the
presence of PSA, and its DP distributions are analyzed simultaneously
by using only as small amount a sample as used for immunochemical
methods. In this study the sample injected to the HPLC column was
derived from 32 mg of wet cell, whereas samples loaded to 1 lane in
SDS-PAGE or added to a well in ELISA were derived from 6 to 16 mg and
50 mg of wet cells, respectively.
The results of DMB/HPLC-FD analysis for the cells harvested at
different stages (24, 36, 48, 60, 72, and 84 h following
inoculation) are reproduced in Fig.
2, A and
B, for IMR-32 and PC-12 cells, respectively. The
appearance of typical ladder-like peaks assignable to DMB-labeled
oligo/poly(Neu5Ac) indicates the presence of PSA in these cells at all
growth stages. The total area of the ladder-like peaks represents the
total number of PSA chains. By analyzing the same amount of the
different cell lines, the level of PSA between the cell lines can be
compared. As can be seen in Fig. 2, A and B
(a-f), the amount of PSA expressed in both IMR-32 and PC-12
cells increased with culture time, and it is most prominent at the full
confluence stage (84 h). The growth stage-dependent change
in PSA expression can be viewed more quantitatively by bar graphs
showing the total peak areas in DMB/HPL-FD as well as the PSA levels
estimated by ELISA and the amount of total protein-bound Neu5Ac (ng/mg
of wet cells) (Fig. 3, A and
B, for IMR-32 and PC-12, respectively). Regardless of the
method used, we can conclude that the PSA level in both cell types
increased with cell culture time and reached the maximum values at
confluence stages (i.e. 84 h culture; after this stage
the number of dead cells increased). In both cell lines, there is some
disagreement between the PSA level estimated by the DMB/HPLC-FD method
and that estimated by ELISA. This discrepancy may be ascribed to the
fact that DMB/HPLC-FD determined the number of PSA chains, whereas
ELISA quantified the number of PSA epitope bound to the antibody.
Results obtained from Western blot analysis were similar to those
obtained from ELISA.
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Fig. 2.
PSA analysis by DMB/HPLC-FD in IMR-32
(A) and PC-12 cells (B) cultured for
24 (a), 36 (b), 48 (c), 60 (d), 72 (e),
and 84 h (f) (full confluence).
Membrane-bound glycoproteins from 100 mg of wet cells at each stage
were solubilized and derivatized with DMB as described under
"Experimental Procedures." Each sample containing 130-950 ng of
total Neu5Ac (derived from 32 mg of cells) was injected into a DNAPac
PA-100 column and eluted with 0.02-0.35 M
NaNO3, and the elution was monitored by fluorescence
intensity. Peaks were labeled with the DP values.
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Fig. 3.
Comparison of PSA levels in IMR-32
(A) and PC-12 cells at different culture times
(B). The levels of PSA were evaluated by three
different methods: (i) PSA analysis by DMB/HPLC-FD (PSA, in arbitrary
unit); (ii) ELISA using anti-PSA (ELISA, in arbitrary unit); and (iii)
total glycoprotein-bound Neu5Ac (Neu5Ac, ng/mg of wet cells).
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Expression and Change in the Level of Polysialylated NCAM in IMR-32
and PC-12 Cells Cultured in the Presence of Retinoic Acid as Evaluated
by Reactivity against Anti-PSA mAb (12F8) and
DMB/HPLC-FD--
Neuroblastoma cells are known to undergo
differentiation into neuronal cells by various chemical agents such as
retinoic acid (RA) (12). We examined the effects of RA added during
cell culture on PSA expression in both IMR-32 and PC-12 cells. The PSA
expression in RA-treated cells harvested at different culture times was
analyzed by Western blot using anti-PSA (Fig.
4, A and B).
Immunostained smear bands showed quite different patterns between
IMR-32 and PC-12 cells. A relatively large smear shown by IMR-32
appearing after the initial 24 h suggests a relatively high level
of PSA-NCAM. The smear size slightly increased until 72 h but
decreased to almost undetectable levels after 84 h. By contrast,
in PC-12 the level of PSA-NCAM was low during the initial stage but
greatly increased in the next 24 h to attain the maximum value
after 48 h. It then gradually decreased and reached the initial
low value after 84 h of culture. The results of PSA analysis by
the DMB/HPLC-FD method in the cells cultured in the presence of RA are
depicted in Fig. 5,
A (IMR-32) and B
(PC-12). Comparing Fig. 5A with Fig. 2A, we can conclude that throughout all culture stages until
the confluence stage (60 h), differentiated IMR-32 cells synthesized larger numbers of PSA chains than the undifferentiated cells. In
RA-treated PC-12 cells, there was no large increase in the number of
PSA chains as in the untreated cells (cf. Figs.
2B and 5B). In contrast, ELISA analysis revealed
a rapid increase in the PSA epitope in RA-treated PC-12, reaching the
maximum value after 48 h, and then gradually decreased. The change
in the number of PSA chains in RA-treated cells at different stages
quantified by the DMB/HPLC-FD was shown as the bar graphs in
Fig. 6, A (IMR-32) and
B (PC-12). The change in the number of PSA epitopes
estimated by ELISA using anti-PSA antibody and the amounts of total
glycoprotein-bound Neu5Ac were also shown in the bar graphs
(Fig. 6, A and B). Again there is disagreement
between the number of PSA chains and that of PSA epitopes.
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Fig. 4.
Western blot analysis of the changes in PSA
expression, using anti-PSA antibody, in IMR-32 (A) and
PC-12 cells (B) during cell culture in the presence of
RA for 24 (lane a), 36 (lane b), 48 (lane c), 60 (lane d), 72 (lane
e), and (lane f) 84 h. A
detergent extract from the cells at each stage was analyzed as
described in Fig. 1.
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Fig. 5.
PSA analysis by DMB/HPLC-FD in IMR-32
(A) and PC-12 cells (B) cultured in
the presence of retinoic acid for 24 (a), 36 (b), 48 (c), 60 (d),
72 (e), and 84 h (f).
Membrane-bound glycoproteins from 100 mg of wet cells at each stage
were subjected to DMB/HPLC-FD analysis as described in Fig. 2.
Peaks are labeled with the DP values.
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Fig. 6.
Comparison of PSA levels in IMR-32
(A) and PC-12 cells (B) at different
culture times in the presence of RA. The levels of PSA were
evaluated by the three different methods as described in Fig.
3.
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Analysis of DP of PSA Chains Expressed in IMR-32 and PC-12 Cells
Cultured in the Absence and Presence of RA--
We confirmed that
DMB/HPLC-FD is an excellent method to determine the DP of PSA (7-9).
We analyzed the distribution of DP in the PSA chains in IMR-32 and
PC-12 cells at different stages cultured in the absence and presence of
RA, and the results are depicted in Fig.
7, A (for IMR-32) and
B (for PC-12). A more prominent difference between the cell
lines was observed in undifferentiated cells. IMR-32 produced higher DP
than PC-12 (compare Fig. 7, A, a, and
B, a). Preferential occurrence of high DP PSA was
observed in undifferentiated IMR-32 cells cultured for 60 h (Fig.
7A, a). The DP distribution pattern observed in
IMR-32 cells at the 60-h stage was similar to that observed for
embryonic day 14 chicken brain NCAM (DP 5-10, 31%; DP 11-20, 32%;
DP 21-30, 24%; and DP >30, 13%) when the highest level of PSA was
synthesized. Although in embryonic chicken brain, PSA of DP >40
occurred at 2% of the total peak area, the cultured cells hardly
showed PSA of DP >40. It should be noted that in these analyses the
total peak areas for the chicken brain sample and the IMR-32 sample
were almost the same, indicating that the appearance of high DP did not
result from a large injected amount. It should also be noted that the preferential occurrence of high DP in IMR-32 cells was observed at the
stage when the number of PSA chains was about 30% of the maximum
expression. RA treatment caused decreased expression of high DP (>30)
PSA chains in IMR-32 (cf. Fig. 7A, a
and b) but no observable changes in PC-12 (cf.
Fig. 7B, a and b). The difference in
DP and DP distribution of PSA chains cannot be analyzed by any existing
immunochemical methods.
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Fig. 7.
DP analysis of PSA chains expressed in IMR-32
(A) and PC-12 cells (B) in the
absence (a) and in the presence (b)
of RA by the DMB/HPLC-FD method. DP distribution was evaluated by
the sum of peak areas of the DMB-oligo/poly(Sia) peaks in each DP range
and expressed as percentage of total.
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Change in Morphology and Cellular Adhesive Behavior of IMR-32 and
PC-12 Cells With and Without RA Treatment--
PC-12 cells were
reported to express two major isoforms of NCAM (NCAM180 and NCAM140)
and undergo neuronal differentiation, e.g. neurite
formation, in response to nerve growth factor (NGF) (17). In this study
the effects of RA on neurite outgrowth and cellular adhesive properties
were examined in cultured IMR-32 and PC-12 cells. When IMR-32 cells
were incubated in the absence of RA, cells formed aggregates at the
initial stages (Fig. 8A, a) and gradually underwent dissociation of cell aggregates
at their later stages (Fig. 8A, b-f). These
changes were associated with a parallel increase in the level of PSA
per unit weight of wet cells (see above). In sharp contrast to these
observations, in the presence of 10 µM RA, IMR-32 cells
did not form aggregates at the initial stages of incubation, and more
than 80% of the cells differentiated to a neuronal phenotype within a
day (Fig. 8B, a). They extended long neuritic
processes during incubation (Fig. 8B, a-e), and
finally after 84 h of culture a large portion of the cells formed
large aggregates (Fig. 8B, f). Similar
morphological changes were observed for PC-12 cells during growth in
the presence of RA (cf. Fig.
9, A and B).
Because cell aggregation can be correlated to the change in the
properties of cell surface molecules including NCAM, the expression
level of PSA must be considered one factor influencing the ability of
cells to aggregate.
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Fig. 8.
Morphological changes of IMR-32 cells
cultured in the absence (A) and in the presence
(B) of RA, for 24 (a), 36 (b), 48 (c), 60 (d),
72 (e), and 84 h(f). Cells at
each stage were examined under a phase-contrast microscope.
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Fig. 9.
Morphological changes of PC-12 cells cultured
in the absence (A) and in the presence
(B) of RA for 24 (a), 36 (b), 48 (c), 60 (d),
72 (e), and 84 h (f). Cells
at each stage were examined under a phase-contrast microscope.
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DISCUSSION |
We have examined the expression of PSA and NCAM in several human
and mouse neuroblastoma and rat pheochromocytoma (PC-12) cell lines by
the recently developed ultrasensitive chemical method (DMB/HPLC-FD) and
also by the Western blot method using anti-PSA and anti-NCAM monoclonal
antibodies as specific immunochemical diagnostic probes. IMR-32 and
PC-12 were PSA-positive/NCAM-positive; neuro-2A was
PSA-negative/NCAM-positive, and SK-N-MC and SK-N-SH were
PSA-negative/NCAM-negative. The overall conclusion was that NCAM
molecule does not occur on all neuroblastoma cells, and PSA is not
expressed on all NCAM immunoreactive cells.
Although neuronal cell type neuro-2A has been widely used as a good
in vitro model for studying neuronal differentiation, apoptotic cell death, and molecules modulating these processes, there
are only a very limited number of studies on PSA expression and enzymes
responsible for the synthesis of PSA chains (18-20). Previous studies
(18) have yielded conflicting results with respect to expression of PSA
in neuro-2A. We first examined neuro-2A as a potential model system for
studying detailed structure-function relationships of PSA chains on
NCAM, but expression of PSA in neuro-2A cells was not detected by
chemical and immunochemical methods. During in vitro
neuronal differentiation of mouse embryonal carcinoma P19 cells, PSA
was found not to be expressed on undifferentiated cells (day 0) or cell
aggregates (days 1-3) but was induced with RA (21). Expression of PSA
began after cell aggregates had been dissociated and re-plated on a
dish (day 4) and increased up to day 7. The expression of
ST8SiaII gene was negligible in both undifferentiated
and aggregated cells, but began at day 4, after RA induction, and
dramatically increased to reach the maximum level at days 6-7. In this
study, neuro-2A cells were analyzed for PSA also under treatment with
RA, but no sign of PSA expression was found.
Therefore, we selected two cell lines, IMR-32 and PC-12, to
characterize their NCAM and PSA expression and morphology in the absence and presence of RA. Some conflicting reports were also found
with respect to the PSA expression in rat PC-12 cells. (i) In 1983 Margolis and Margolis (22) reported the possible presence of PSA in the
highly negatively charged glycopeptides derived from PC-12 cells. (ii)
Livingston et al. (10) reported the possible presence of an
endogenous PSA because a membrane fraction of PC-12 cells acted as an
endogenous acceptor of [14C]Neu5Ac in an
Escherichia coli K1 sialyltransferase assay. (iii) The
calcium-independent protein kinase C
isozyme was reported to be
inversely related to NCAM polysialylation state in rat PC-12 cell line
(18). (iv) Horstkorte et al. (23) reported that PC-12 cells
only produce a stable polysialylated NCAM when transfected with ST8SiaIV.
Until now two techniques were usually employed to evaluate the amount
of PSA expression and DP of PSA chains as follows: one is ELISA and the
other is assessment of the intensity and migration rate of smear bands
on Western blot. In a recent study of RA-induced changes in PST
(ST8SiaII and ST8SiaIV) mRNA expression level and NCAM
polysialylation of human neuroblastoma (SH-SY5Y and LAN-5) cells, the
increased expression of ST8SiaIV was shown to be closely related to an
accelerated polysialylation of NCAM estimated by ELISA (13), although
it remains to be determined if there exists any difference in DP of PSA
chains produced by ST8SiaII and ST8SiaIV.
In this study three methods were used to assess the expression level of
PSA during growth and differentiation of neuroblastoma and
pheochromocytoma cells: (i) DMB/HPLC-FD analysis (total peak area
measurements); (ii) ELISA; and (iii) determination of total protein-bound Neu5Ac (Figs. 3 and 6). The results provide the first
quantitative analyses of changes in the NCAM polysialylation level
during cell growth and differentiation. The three methods were used to
compare the expression level of PSA during cell growth before and after
RA treatment (Figs. 3 and 6). We noted significant disagreement in the
PSA levels estimated by DMB/HPLC-FD and ELISA methods for some samples.
This may be partly because DP distribution patterns of PSA chains
expressed on a variety of NCAM glycoforms are not simple, and anti-PSA
antibody could not accurately quantify PSA, as we have repeatedly
emphasized (6-9). The antigen specificity resides in the DP of PSA
chains, and oligomers as low as DP 3 and 4 can be recognized by some
anti-PSA antibodies. It is also uncertain at this moment how many
antibody molecules can bind to NCAM glycoforms having larger PSA chains
(DP 
20). We can thus conclude that the discrepancy in the
values obtained by either chemical or immunochemical methods is
ascribable to the nature of their reactions. The DMB/HPLC-FD method
appears to be superior to the immunochemical methods because it
provides information on the DP of PSA chains. Unfortunately, in a
number of recent papers (12, 13) reporting studies of the
correlation between polysialyltransferase mRNA expression and NCAM
polysialylation, the estimation of PSA was based on PSA
immunoreactivity, and they may not depict entirely accurate information.
Precise information not only on DP of PSA chains on NCAM but also on
their distribution is considered important in understanding (i) the
molecular mechanism of biosynthesis of PSA chains, i.e. correlation of poly(ST) with DP of PSA, (ii) fine-tuning of NCAM-NCAM adhesive interaction by PSA chains on NCAM glycoforms, and (iii) correlation of PSA chain length and the metastatic potential of neuroblastoma cells or more in general tumor progression. Some estimates of PSA chain lengths were done by the elution positions on
anion-exchange chromatography of PSA-containing glycopeptides derived
from PSA-NCAM (24, 25). DP values thus obtained may be significantly
overestimated because sulfate groups were shown to be present on the
core glycan chains (22, 26-28). Moreover, this method also suffers
from the fact that it measures the total numbers of Sia and sulfate
residues per N-glycan chain. In addition, a possible
attachment of PSA chains on the two antennae of a single core
N-glycan should be taken into account (26). We believe that
the DMB/HPLC-FD method will alleviate these shortcomings in future
studies in these areas.
The goals of our present line of study are as follows: (i) to
characterize a divergent number of NCAM glycoforms differing in the DP
of PSA expressed in different cell types under different physiological
conditions; (ii) to correlate invasive growth and metastatic potential,
if any, of NCAM-expressing tumor cells and NCAM glycoforms with varying
DP values, and (iii) to determine how a large number of such NCAM
glycoforms regulate differentially the strength of cell-cell and
cell-substratum adhesive interaction mediated by NCAM. In particular,
concerning an as yet unanswered question related to the biosynthesis of
PSA chains on NCAM, it is still uncertain how the levels and DP
distribution of the PSA chains are regulated at different stages of
development. Although it has become certain that two
polysialyltransferases, ST8SiaIV and ST8SiaII, are involved in
catalysis of polysialylation of NCAM (24, 25, 29-38), it still remains
unanswered what is the specific role of each of the two closely related
polysialyltransferases. No clear data are available to answer the basic
question as to whether there exists any difference in DP value of
poly(Sia) chains formed by ST8SiaIV and ST8SiaII.
Many forces need to be considered in order to consider the sources of
counter-adhesive properties of PSA in NCAM. As cell membranes are
brought together they experience several types of forces such as van
der Waals attraction, electrostatic attraction/repulsion, hydration
repulsion, and specific charge-charge interactions. Counter-adhesive
processes in PSA-NCAM may predominantly involve steric hindrance
(hydration repulsion) (39) and, perhaps less significantly, charge
repulsion of PSA chains. Our results strongly suggest that PSA chains
with DP values of 20-30 appear to be long enough to inhibit homophilic
adhesion of NCAM. PSA chains of more than DP 30 occur much less
frequently, if ever, and such long PSA chains may not be necessary to
prevent aggregation of neural cells. In the present study, the largest
DP of PSA on NCAM by DMB/HPLC-FD was 45 (this method permits us to
detect PSA up to DP 90 when colominic acid was analyzed). These results
lead us to question whether high DP PSA chains (DP >40), which occur
on only a tiny proportion of NCAM molecules at certain stages of growth
and differentiation, are of biological significance.
| |
FOOTNOTES |
*
This work was supported by National Science Council Grants
NSC 90-2311-B-001-102 (to S. I.) and NSC 90-2311-B-001-140 (to Y. I.)
and National Health Research Institutes Grant NHRI-EX90-8805BP (to
Y. I.).The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
To whom correspondence should be addressed. Fax: 886-2-2788-9759;
E-mail: syinoue@gate.sinica.edu.tw.
Published, JBC Papers in Press, May 21, 2002, DOI 10.1074/jbc.M202731200
| |
ABBREVIATIONS |
The abbreviations used are:
Sia, sialic acid;
Neu5Ac, N-acetylneuraminic acid or
2-keto-3,5-dideoxy-5-acetylamino-D-glycero-D-galacto-nononic
acid;
PSA or poly(Sia), polysialic acid or 28-linked
oligo/poly(Neu5Ac);
DP, degree of polymerization;
DMB, 1,2-diamino-4,5-methylenedioxybenzene;
NCAM, neural cell adhesion
molecule;
PSA-NCAM, polysialylated NCAM;
HPLC, high performance liquid
chromatography;
DMB/HPLC-FD, high performance liquid chromatography
with fluorescence detection of ulosonates after derivatization with DMB
reagent;
RA, retinoic acid;
mAb, monoclonal antibody;
ELISA, enzyme-linked immunosorbent assay;
MOPS, 4-morpholinepropanesulfonic
acid.
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ABSTRACT
INTRODUCTION
