(Received for publication, October 22, 1996, and in revised form, December 19, 1996)
From the Glycobiology and Neurobiology Programs, La Jolla Cancer
Research Center, The Burnham Institute, La Jolla, California 92037 and Central Clinical Laboratories, Shinshu University
Hospital, Matsumoto 390, Japan
PST and STX are polysialyltransferases that form
polysialic acid in the neural cell adhesion molecule (N-CAM), although
it is not known why these two polysialyltransferases exist. In the present study, we have first isolated cDNA encoding human STX, which includes 5-untranslated sequence. Northern blot analysis, using
this cDNA and PST cDNA previously isolated by us, demonstrated that PST and STX are expressed in different fetal and adult tissues. STX is primarily expressed in embryonic tissues, but only modestly in
adult heart, brain, and thymus. PST, on the other hand, is continuously
expressed in adult heart, brain, thymus, spleen, small and large
intestines, and peripheral blood leukocytes. In various parts of adult
brain, the relative amount of PST and STX appears to be substantially
different depending on the regions. The analysis by in situ
hybridization of mouse adult brain, however, suggests that polysialic
acid in the hippocampal formation is synthesized by both STX and PST.
HeLa cells doubly transfected with the isolated STX cDNA and N-CAM
cDNA supported neurite outgrowth much better than HeLa cells
expressing N-CAM alone. However, polysialic acid synthesized by PST
appears to be a better substratum than that synthesized by STX.
Moreover, the genes for PST and STX were found to reside at chromosome
5, band p21 and chromosome 15, band q26, respectively. These results,
taken together, strongly suggest that PST and STX are expressed
distinctly in tissue-specific and cell-specific manners and that they
apparently have distinct roles in development and organogenesis.
Polysialic acid is a developmentally regulated glycan composed of
a linear homopolymer of -2,8-linked sialic acid residues. Polysialic
acid is mainly attached to the neural cell adhesion molecule
(N-CAM)1 and is more abundant in embryonic
brain than adult brain (1-3). Presence of this large negatively
charged carbohydrate modulates the adhesive property of N-CAM, and
removal of polysialic acid increases binding between N-CAMs (4, 5).
During embryonic development, the polysialylated embryonic from of
N-CAM is restricted to migrating cells (6, 7), and the removal of
polysialic acid from the N-CAM during embryonic development affects
motor-axon projection patterns (8). Polysialylated N-CAM was also shown to attenuate cell-cell interactions mediated by other cell
adhesion molecules (9-11).
Recently, we and others have cloned cDNAs encoding human, hamster, and mouse polysialyltransferases (PST for human, PST-1 for hamster, and ST8Sia IV for mouse, respectively) (12-14). The amino acid sequences of PST and PST-1 are more than 97% identical. Both PST and PST-1 directed the expression of polysialic acid on the cell surface. The same studies also revealed that PST is highly homologous to STX (sialyltransferase X, or ST8Sia II) (12, 13), and STX and PST have 59% identity at the amino acid level. STX was originally cloned as a developmentally regulated sialyltransferase from the rat fetal brain (15). Although the substrate specificity of STX was not known at the time of its discovery, the above results prompted investigation of STX as a polysialyltransferase. In support of this speculation, it was shown that STX also directs the expression of polysialic acid in small cell lung carcinoma cell lines (16) and forms polysialic acid in both wild-type N-CAM as well as soluble chimeric N-CAM proteins (17).
Consistent with the presumed roles of polysialic acid, it has been shown that PST facilitates neurite outgrowth (12). HeLa cells were transfected with human PST and N-CAM cDNAs or N-CAM cDNA alone and used as the substratum for the neurite outgrowth assay. When neurons derived from embryonic chicken were grown on these substrata, neurites were much longer and more branched on the substratum cells expressing polysialic acid and N-CAM than those on the substratum expressing N-CAM alone (12). These results clearly indicate that polysialic acid formed by PST facilitates neurite outgrowth. However, it is not known if expression of STX and N-CAM cDNAs also facilitates neurite outgrowth.
By using an in vitro assay system, both PST and STX added
polysialic acid to fetuin and soluble chimeric N-CAM (17, 18). This
demonstrates that either PST or STX alone can form polysialic acid by
adding the first -2,8-linked sialic acid to
-2,3-linked sialic
acid in a glycoconjugate template, followed by multiple
-2,8-linked
sialic acid residues to the acceptor containing
NeuNAc
2
8NeuNAc
2
3Gal
R structure. PST and STX thus appear
to share common enzymatic properties. On the other hand, it is not
known why these two enzymes exist for polysialylation.
In order to address this question, in the present study we have compared the expression profile of PST and STX in various fetal and adult tissues using Northern blot analysis and in situ hybridization. In addition, we have analyzed PST and STX in their capability to promote neurite outgrowth. Moreover, we demonstrate the presence of genes encoding PST and STX on different chromosomes, implying early separation in their evolution. These results strongly suggest that PST and STX play distinct roles in development and organogenesis.
First, cDNA was
synthesized from the human fetal brain mRNAs (Clontech) using a
3-primer and reverse transcriptase. The 3
-primer, ASTX-3-1, is
5
-GTCCTCC
-3
. The last 15 nucleotides in
this sequence correspond to nucleotides 1114-1128 of human STX, hSTX
sequence (nucleotides 1126-1128 encode the stop codon) (16). The rest
of ASTX-3-1 sequence was adapted from the mouse STX (mSTX) sequence
(19). By reverse transcriptase-catalyzed reaction, cDNA was
produced, and PCR was performed using the formed cDNA as a template
to amplify the sequence between nucleotides 96 and 1128 (nucleotides
1-3 and nucleotides 1126-1128 encode the initiation and the stop
codon, respectively). The primer sequences were based on the hSTX
sequence (16).
In order to obtain the sequence upstream from nucleotide 96, cDNA
was synthesized using a 3-primer corresponding to nucleotides 188-199, reverse transcriptase, and human fetal brain mRNAs as a
template. PCR was then carried out using the formed cDNA as a
template. The 5
-primer, STX-XbaI, for this PCR is
5
-GC
CCTCGCCCCGGCCCG-3
, in which the last 15 nucleotides encode nucleotides
40 to
26 of mSTX (19). The rest of
the sequence contains XbaI site (denoted by an underline).
The 3
-primer sequence corresponds in antisense direction to
nucleotides 110-133 of hSTX. The PCR product obtained was cloned into
pBluescript II (Stratagene) and then digested at HindIII
site in the vector and at an internal EcoRI site
(nucleotides 99-104). This HindIII-EcoRI
fragment was appended to the 5
-end EcoRI site of a larger
cDNA fragment (encompassing nucleotides 100-1283), producing a
full-length cDNA encoding hSTX. The ligated cDNA was cloned
into the HindIII and XhoI sites of
pcDNAI.
Northern
blots of poly(A)+ RNA from human fetal (19-23 gestational
weeks) and adult brains, as well as human multiple tissue Northern
blots of poly(A)+ RNA, were purchased from Clontech. These
blots were hybridized with a gel-purified cDNA insert of
pcDNAI-hSTX or pcDNAI-hPST after labeling with
[-32P]dCTP by random-oligonucleotide priming (20)
(Prime It-II labeling kit, Stratagene).
A mouse genomic DNA library derived from 129 SVJ mouse
genome (Stratagene) was screened with a DNA fragment that represents the 5-portion of human PST cDNA (12). One of the isolated genomic clones, I15, contains the exon surrounding the translation initiation methionine of mPST judging from the comparison of human PST cDNA and mouse genomic sequences. Subsequently, this was verified by comparison of this sequence and the mPST cDNA sequence reported later (14). The details of the isolation of mouse genomic DNA will be
described elsewhere.
Using this clone I15 as a template, mPST cDNA sequence surrounding
the initiation methionine (nucleotides 47 to 113; the first
nucleotide of the initiation codon is +1) was amplified by PCR. The
5
-primer and 3
-primer are 5
-GC
AGGTGCCTGAGCTGG-3
and 5
-CGG
GATGAGTTGCGTCTCTT-3
, respectively. The
XbaI and KpnI sites are denoted by an underline.
The sequence of the 3
-primer ends at the 3
-end of the exon, which was
deduced from the comparison of the mouse genomic and human PST cDNA
sequences. This amplified cDNA sequence was cloned into
XbaI and KpnI sites of pBluescript II SK, and the
resultant vector was used as a template for the construction of RNA
probes. A digoxigenin-labeled antisense RNA probe was produced using
the XbaI-cut template and T7 RNA polymerase with the DIG RNA
labeling kit (Boehringer Mannheim). Similarly, a sense probe for a
negative control experiment was prepared using the
Asp718-cut template and T3 RNA polymerase with the same
kit.
In order to obtain the 5-region of mSTX cDNA, cDNA
was synthesized by reverse transcriptase, SuperscriptTM II (Life
Technologies, Inc.) using poly(A)+ RNA from mouse brain
(Clontech) and the primer oligonucleotide 5
-TTCACAGCTGATCTGATTGT-3
synthesized according to the published sequence (nucleotides 118-137,
Ref. 19). Using this cDNA as a template, the 5
-region of mSTX
sequence was amplified by PCR. The 5
-primer, STX-XbaI is
described above and the 3
-primer is 5
-CGG
AGAATTCCCGATTTCTTC-3
(nucleotides 88-107)
(underlined sequence denotes KpnI site). The obtained
cDNA was cloned into XbaI and KpnI sites of
pBluescript II SK, and used as a template to produce RNA probes.
Hybrid-Ready tissue slides of mouse adult brain (NIH Swiss strain) were purchased from Novagen. In situ hybridization was performed as described previously (21). The sections were subjected to immunohistochemistry for detection of the hybridized probes by using alkaline phosphatase-conjugated anti-digoxigenin antibody with the DIG nucleic acid detection kit (Boehringer Mannheim). The alkaline phosphatase reaction was demonstrated by 5-bromo-4-chloro-3-indolyl phosphate and nitro blue tetrazolium in the presence of 10% polyvinyl alcohol (22). Control experiments using sense probes for PST or STX produced no specific signals.
Immunohistochemistry for Polysialic AcidThe Hybrid-Ready tissue slides were subjected to the immunohistochemical staining for detection of polysialic acid as described previously (12, 23). A monoclonal antibody 12F8 specific for polysialic acid (24) (Pharmingen) was used in this study, and immunochemical detection was performed by indirect method using anti-rat immunoglobulins conjugated with horseradish peroxidase (Dako) (25), followed by counterstaining with hematoxylin. A control experiment was done by omitting the antibody 12F8 from the staining procedure, and no specific staining was found. The results obtained using antibody 12F8 were confirmed by using antibody 735 (26) or 12E3 (27).
Assay for Neurite Outgrowth on HeLa Cells Stably Expressing N-CAM and PSASince HeLa cells were negative for both PSA and N-CAM,
they were transfected by a plasmid pHAPr-1-neo-N-CAM encoding
N-CAM140 (28) using LipofectAMINE (Life Technologies, Inc.). After
selection with G418, clonal cell lines stably expressing N-CAM were
selected by staining with anti-N-CAM antibody, CD56 (Dako). A clonal
HeLa cell line expressing N-CAM was then transfected with
pcDNAI-STX and a plasmid pSV2HyB encoding the
hygromycin resistance gene, and HeLa cells expressing both N-CAM and
polysialic acid (detected by 12F8 antibody), named HeLa-N-CAM+STX
cells, were selected. HeLa cells expressing both N-CAM and PST, termed
HeLa-N-CAM+PST, were established as described (12). These cells were
cultured as monolayers in Lab-Tek chamber slides (Nunc). Sensory
neurons were obtained from the dorsal root ganglia of 10-day-old
chicken embryos. These neurons were dissociated with trypsin (0.5%),
counted, seeded at low density over HeLa cell monolayers, and cultured in minimum essential medium containing 10% fetal bovine serum (29,
30). Nerve growth factor was included in the sensory neuron culture.
Neuron-HeLa cell cocultures were grown for 15 h, fixed with 4%
paraformaldehyde in phosphate-buffered saline, and stained with
anti-neurofilament antibody RM0270 (31), followed by fluorescein
isothiocyanate-conjugated anti-mouse IgG antibody. Neurite lengths were
measured with the Metamorph Imaging system (Universal Imaging Corp.,
West Chester, PA) as described previously (12). The mean neurite
lengths and the number of branch points per neuron were compared among
the different substrate conditions by Student's t test.
HeLa-N-CAM, HeLa-N-CAM+PST, and HeLa-N-CAM+STX cells were subjected to Western blotting using the ECL Western blot detection system (Amersham) as described (12) with a modification. Briefly, the cell pellet was recovered by centrifugation and a portion of the pellet was digested with endo-N (32). The cells were then dissolved in 1% Nonidet P-40 containing a protease inhibitor mixture (Boehringer Mannheim) in phosphate-buffered saline, and the supernatant obtained after centrifugation was incubated with an equal volume of wheat germ agglutinin (WGA)-agarose (EY Laboratories). After incubation with rotation, the suspension was briefly centrifuged and the WGA-agarose beads were recovered. The glycoproteins were dissociated from WGA-agarose by heating at 85 °C for 3 min in the sample buffer for electrophoresis (18). The proteins, separated by 5% SDS-polyacrylamide gel electrophoresis, were blotted to PVDF membrane and treated in 0.01 N HCl at 80 °C for 20 min, followed by blocking with 10% skim milk. The membrane was then incubated with anti-N-CAM antibody, CD56 (Becton Dickinson). For detection of polysialic acid, the blotted PVDF membrane without acid pretreatment was incubated with 12E3 antibody (27). The 12E3 antibody was kindly provided by Dr. Yasumasu Arai, Juntendo Medical School, Tokyo, Japan.
Fluorescence in Situ Hybridization Analysis of PST and STX GenesP1 plasmid human genomic DNA library was screened by PCR as
described (34). The 5 and 3
primers for PCR of PST gene correspond to
the PST sequence of nucleotides 599-608 and that of nucleotides 757-776, respectively. Purified DNA from one of the clones, clone 6029, was labeled with digoxigenin-dUTP by nick translation. Labeled probe was combined with sheared human DNA and hybridized to normal metaphase chromosomes derived from phytohemagglutinin-stimulated peripheral blood leukocytes, and the chromosome banding was carried out
as described (35).
Similarly, P1 plasmid human genomic DNA library was screened for STX
gene by PCR. The 5- and 3
-primers for this PCR correspond to the STX
sequence of the nucleotides 954-972 and that of the nucleotides
1101-1118, respectively. Purified DNA from one of the isolated clones,
clone 6747, was used as a probe as described above.
There were two reports on
human STX (hSTX) sequences that differ in several nucleotides,
including the stop codon (16, 33). In order to determine whether or not
either sequence was correct and if allelic differences might exist, we
cloned hSTX cDNA. First we cloned the cDNA encompassing
nucleotides 96-1128 by synthesizing cDNA using human brain
mRNA as a template. This was only possible using the nucleotide
sequence reported by Scheidegger et al. (16). When primers
were synthesized according to the 3-end sequence reported by another
laboratory (33), no PCR product was formed. We then tried to extend
this sequence upstream to 5
-untranslated sequence since there is no
information on this sequence of human STX even in the data bank. This
sequence was also necessary to express STX protein in mammalian cells.
The 5
-untranslated sequence was obtained by reverse transcriptase-PCR
using the 5
-primer sequence adapted from mouse STX and human fetal
brain mRNA as a template. This 5
-upstream sequence was ligated to
the above large cDNA fragment at a common EcoRI site to
form a cDNA encompassing a single long open reading frame predicted
to code the entire hSTX polypeptide.
Fig. 1A shows the 5-region of the nucleotide
and amino acid sequences of hSTX obtained by the above experiments. The
nucleotide sequence from codon 1 to the stop codon was found to be
identical to that of Scheidegger et al. (16). The amino acid
sequences of hSTX and hPST have 58.8% identity. As shown in Fig.
1B, the similarity is more significant in the catalytic
domains of STX and PST.
Expression of STX and PST Transcripts in Various Human Fetal and Adult Tissues
In order to understand how STX and PST differ, the
expression of STX and PST transcripts were examined by Northern blot
hybridization using the same blot. Although the expression of hSTX and
hPST transcripts were reported individually (12, 33), there is no
report on the direct comparison of two enzymes side by side, nor is
there any report on STX expression in various parts of the brain. The
results shown in Fig. 2 demonstrate that STX transcripts are much more abundant in fetal brain than adult brain (for adult brain, see the whole brain in multiple brain tissues). Among adult tissues, the STX transcript is relatively abundant in thymus and heart,
and moderately present in the small intestine, colon, and skeletal
muscle. Among adult brain tissues, the STX transcript is present
prominently in hippocampus, medulla oblongata, and putamen and
moderately in amyglada, cerebral cortex, subthalmic nucleus, and
cerebellum. In contrast, the PST transcript is more prominent in
amyglada, subthalmic nucleus, cerebral cortex, and occipital pole (Fig.
2). PST is moderately detectable in hippocampus where STX is
prominently present. PST is also abundant in fetal brain, but the
difference in the PST transcript between fetal brain and fetal lung or
kidney is much less than that of STX transcript. In adult tissues, PST
is more widely present in non-neural cells. In particular, a
substantial amount of the PST transcript is present in spleen and
peripheral blood leukocytes, where STX is hardly expressed. PST was
also expressed in placenta where STX was not detected. These results
suggest that STX is more dramatically reduced during embryonic
development and its expression is restricted to only a few tissues in
adult. PST is also substantially reduced during development of brain
but persists in some non-neural tissues.
The specific hybridization by PST or STX probe was confirmed by the fact that only PST or STX transcript could be detected in certain tissues. For example, only PST transcript was detected in placenta while only STX transcript was detected in cerebellum. Moreover, the relative intensity of each transcript in different tissues did not change even after more stringent washings.
Expression of mPST and mSTX Determined by in Situ Hybridization in the HippocampusThe above results indicate that STX is more
dominant than PST in the hippocampus. In order to determine which cells
express these enzymes, in situ hybridization was carried out
using mouse brain. In the hippocampus formation, a significant amount
of the signal for the mPST transcript was detected in the granule cells of the dentate gyrus as well as the pyramidal cells medially located in
the CA1 and CA3 fields of the Ammon's horn (Fig.
3A). In CA3, the mPST transcript was barely
detectable, and the CA2 field lacked the mPST transcript. In contrast,
a strong signal for the mSTX transcript was detected not only in CA1
and the granule cells of the dentate gyrus, but also in CA2 and CA3
(Fig. 3B). Polysialic acid, on the other hand, was expressed
in the granule cells of the dentate gyrus and the mossy fibers arising
from these granule cells (Fig. 3D), and this staining
pattern is consistent with results shown in the previous report (36).
These results combined together indicate that the polysialic acid in
the granule cells are coordinately synthesized by mPST and mSTX, and
most likely transported to the mossy fibers through axoplasmic
flow.
Expression of Polysialylated N-CAM by STX
We have shown
previously that the expression of PST and N-CAM cDNAs in HeLa cells
resulted in the expression of polysialic acid on N-CAM (12). In the
present study, HeLa cells were stably transfected with the cloned STX
and N-CAM cDNAs. As shown in Fig. 4, HeLa cells
express both N-CAM and polysialic acid detected by immunofluorescent
staining using anti-N-CAM and anti-polysialic acid antibodies (Fig. 4,
G and H). The immunostaining of polysialic acid
was abolished after endo-N treatment of the cells (Fig. 4J). In parallel, HeLa cells transfected with N-CAM and PST cDNAs were examined. Those HeLa cells showed a positive staining for N-CAM before
and after endo-N treatment (Fig. 4, C and E),
while polysialic acid staining disappeared after endo-N treatment (Fig.
4, D and F).
In order to determine whether or not STX actually formed polysialic
acid on N-CAM, the cell lysates from the above stably transfected HeLa
cells were subjected to Western blot analysis. A diffused high
molecular band detected in cell lysates was converted to a sharp low
band after endo-N treatment (Fig. 5, left
panel, lanes 5 and 6). Almost identical
results were obtained on HeLa cells expressing both N-CAM and PST (Fig.
5, left panel, lanes 3 and 4). Such a
broad smear band was not obtained in parental HeLa cells which were
transfected only with N-CAM cDNA (Fig. 5, left panel,
lanes 1 and 2). These results indicate that both
STX and PST can form polysialic acid on N-CAM.
In order to specifically detect the polysialylated form of N-CAM, the blot was incubated with anti-polysialic acid antibody, 12E3, without acid pretreatment. As shown in Fig. 5 (right panel), a highly polysialylated form of N-CAM with high molecular weight was detected in both PST and STX-transfected cells (lanes 3 and 5) and those broad bands with high molecular weight were not detected after endo-N treatment (lanes 4 and 6). These highly sialylated N-CAM are much larger than those detected by anti-N-CAM antibody (compare right and left panels), consistent with the results reported previously (37).
Neurite Outgrowth on HeLa Cells Transfected with STX and N-CAMNeural cell migration and axon outgrowth are influenced by
polysialic acid expression on neural cells (29, 30). To determine the
effect of polysialic acid synthesized by STX on N-CAM, HeLa cells
expressing N-CAM alone was used as a parental cell line in establishing
HeLa-N-CAM+STX. Neuronal cells derived from dorsal root ganglion were
grown on HeLa substratum cells and found to exhibit modest outgrowth on
confluent monolayers of HeLa cells expressing N-CAM alone (Fig.
6A). In contrast, neurons cultured on HeLa
cells, which were transfected with both STX and N-CAM to express
polysialylated N-CAM, grew neurites significantly longer and exhibited
more branching (Fig. 6C) than those grown on N-CAM alone
(Fig. 6A). This enhanced effect by polysialic acid was
abolished once the substratum cells were treated with endo-N before the assay (data not shown). Very similar results were obtained on HeLa
cells that were transfected with PST and N-CAM to express polysialylated N-CAM (Fig. 6B), as shown previously
(12).
The results summarized in Fig. 7 show clearly that
polysialylated N-CAM produced by STX and PST show very similar
enhancement in neurite outgrowth, although PST-transfected HeLa cells
appear to be better substrates than STX-transfected cells. This
difference in the efficiency can be observed in both the length of the
neurites and the number of branch points. In experiment 2, for example, the neurite lengths of PST- and STX-expressing cells were 301 ± 8.4 µm (n = 80) and 260 ± 7.0 µm
(n = 91), respectively, showing a significant
difference between two cell lines (p < 0.001).
Similarly, the branch points were 3.0 ± 0.24 (for PST,
n = 80), and 2.3 ± 0.17 (for STX,
n = 91), showing substantial difference
(p < 0.01). In experiment 1, the difference in the
length was not substantial but the difference in the branch points was
noted. These results strongly suggest that PST-transfected HeLa cells
were better substrates than STX-transfected HeLa cells in this
particular set of cell lines used.
The Genes of PST and STX Reside in Different Chromosomes
Fig. 2 also shows that the major transcript of PST and STX is almost the same size, ~6.8 kilobases. In addition, STX mRNAs contain minor bands of ~3.9 and ~2.6 kilobases, while the minor transcripts of PST migrate at ~4.1 kilobases. It thus appears that the size and pattern of the major transcripts for PST and STX are very similar. However, the size of minor transcripts differ, confirming the above conclusion that these detected bands are specific to the transcripts of PST and STX. Among different sialyltransferases, the similarity in the amino acid sequences between PST and STX is the highest and no other similarity between different members of sialyltransferase reaches 59% (12, 13). These results suggest that PST and STX are highly related to each other.
In order to determine how closely the PST and STX are related to each
other in gene localization, we utilized fluorescence in situ
hybridization procedure to localize PST and STX genes. First, P1
plasmids harboring PST and STX genes, named clone 6029 and 6747, respectively, were isolated. Genomic DNA was prepared from these P1
clones and used as a probe. The first clone, 6029, was found to
hybridize to the middle of the long arm of a group B chromosome. Two
additional experiments using two known probes, which hybridized to 5q34
or 5p15, showed that 6029 is located on chromosome 5. Measurements of
10 specifically hybridized probes to chromosome 5 demonstrated that
6029 containing PST gene is located on chromosome 5 arm q at a position
which is 43% of the distance from the centromer to the telomere, and
at the area that corresponds to band q21 (Fig. 8,
A and C).
Similarly, genomic DNA clone 6747, which contains STX gene, was localized to chromosome 15, band q26 (Fig. 8, B and D). These results clearly indicate that PST and STX are localized on different human chromosomes.
In the present study, we have isolated human STX cDNA and
obtained the 5-untranslated sequence. It is likely that the adenosine at nucleotide 1 represents the first nucleotide of the translation initiation methionine for the following reasons. First, the nucleotide sequence surrounding the initiation methionine, CCC
CCATG,
conforms with Kozak's sequence, GCC
CCATG, reported for
the optimum context for initiation of translation (38). The sequence
surrounding the second methionine codon (nucleotides 25-27) is
entirely different from this context (see Fig. 1A). Assuming
that mSTX and hSTX share the common 5
-untranslated sequence, no
methionine codon is found in the upstream sequence (19) as well as in
the determined sequence upstream from the presumed initiation
methionine (Fig. 1A). Finally, the expression of the
obtained cDNA directed the expression of polysialic acid. We have
also shown that hSTX and hPST are highly homologues to each other. The
similarity is more extensive in the whole catalytic domain, which
includes sialyl motif L, the binding site of the donor CMP-NeuNAc (39),
and sialyl motif S than in the transmembrane domain and stem region.
This similarity in the catalytic domain must reflect that both enzymes
have polysialylation activity, whereas dissimilar regions may
contribute to the difference in their functions (Fig.
1B).
In the present study, we have shown that hSTX forms polysialic acid on N-CAM, and thus has the same function as mSTX (17). In the previous studies, we and others have shown that PST also forms polysialic acid on N-CAM (12, 13, 17). It is then important to know why these two polysialyltransferases are present and how they work differently. The first clue to understanding this question was derived from Northern blot analysis in the present study. The results obtained with Northern blot analysis were striking (Fig. 2). In human fetal tissues, hSTX is much more abundant in brain than lung, liver, and kidney. Such a tremendous difference was not observed in hPST, although it is still expressed much more in the fetal brain than other fetal tissues. In comparison, both hSTX and hPST are moderately expressed in human adult brain. However, there is a substantial difference in PST and STX expression in other tissues. While hSTX is expressed moderately in thymus and heart, hPST is also expressed in spleen, peripheral blood leukocytes, and small and large intestines. Although hSTX is dominantly expressed in some regions of the adult brain than hPST, no tissue was found where hSTX is expressed but hPST is absent as far as we examined. These combined results indicate that each PST and STX function in specific tissues, in which either enzyme likely plays a dominant role in a particular tissue. The results also suggest that the expression of these two enzymes are differently regulated.
Previously we have shown by immunostaining using 735 antibody that thymus and small and large intestines express polysialic acid (12). It has been also shown that NK cells and NK-derived leukemic cells express polysialic acid as well as N-CAM (40, 41). The polysialic acid in these cells are most likely synthesized by PST. In contrast, hSTX was shown to direct the polysialic acid synthesis in small cell lung carcinoma cells (16), and is more dominant in certain parts of adult brain, as shown in the present study. For example, the signal for the hSTX transcript in hippocampus was more significant than the hPST transcript. This result was confirmed by in situ hybridization of mSTX and mPST in hippocampus of mouse adult brain. The same experiments, however, demonstrated that mPST and mSTX are expressed in overlapping but different parts of hippocampus (Fig. 3). Hippocampus is one of the few tissues where polysialic acid is continuously synthesized in adult (36, 42). It has been shown previously that polysialic acid and most likely N-CAM are synthesized in newly generated granule cells (36, 43). Since both the STX and PST transcripts were detected in those cells, these combined results strongly suggest that both STX and PST are responsible for polysialic acid formation in the dentate granule cells and mossy fibers in the hippocampus. It is noteworthy that N-CAM knockout mice have deficiency in the development of the CA3 region (44), where the STX transcripts are highly expressed. These results are consistent with the conclusion that the defect in N-CAM knockout mice is due to the absence of polysialylated N-CAM (44, 45). The results also suggest that human and mouse probably show the common feature in the expression profiles of PST and STX in the hippocampus, since Northern blot analysis of human hippocampus and in situ hybridization analysis of mouse brain showed similar results as a whole.
We have shown previously that neurons extend longer and have more branches on HeLa cells that were transfected with PST and N-CAM cDNAs than those transfected with N-CAM cDNA alone (12). In the present study, we have demonstrated that hSTX can form polysialylated N-CAM, and also introduces the capability of N-CAM to facilitate neurite outgrowth. These results strongly suggest that STX and PST play critical roles in neural development and axon growth. We also noted that HeLa-N-CAM cells transfected with STX appear to be slightly less efficient as substratum in neurite outgrowth than those with PST (Fig. 7). This is rather surprising, since HeLa-N-CAM+STX cells apparently contain more polysialylated N-CAM than HeLa-N-CAM+PST when these particular cell lines utilized are compared (Fig. 5B). It is possible that only a small portion of N-CAM, which is heavily polysialylated, may be critical for neurite outgrowth or that different polysialic acid structures may be synthesized by these two enzymes. Alternatively, too high a concentration of polysialic acid may be less efficient in neurite outgrowth. Further studies are necessary to determine which is the case.
Despite the fact that hPST and hSTX have 59% identity in amino acid
sequences, these two enzymes are located on entirely different chromosomes. Moreover, GD3/GT3 synthase, another
-2,8-sialyltransferase related to PST or STX, is located on
chromosome 12, band p12 (35). These results strongly suggest that these
three sialyltransferases diverged from an ancestral gene early in
evolution. These results are similar to those recently reported
demonstrating that two different
-2,3-sialyltransferases are located
on entirely different chromosomes (46). It will be of significance to
analyze the difference in the regulatory sequences between hPST and
hSTX genes, since the separation into different chromosomes might have
resulted in the diversion of their regulatory elements as well. It is, on the other hand, noteworthy that hPST is located on chromosome 5, band q21. An isozyme of
-mannosidase II,
-manIIx, was
also located to chromosome 5, band q21, while
-mannosidase II
resides on chromosome 15, band q25 (47). Moreover, a tumor suppressor
gene, the adenomatous polyposis coli (APC) gene, is located on 5q21
(48). It will be interesting to determine if PST and APC genes are
present in close proximity and if the expression of polysialic acid in
certain tumors might be caused by gene alteration, which also causes
inactivation of APC gene.
In summary, both PST and STX can polysialylate N-CAM, but these two enzymes apparently play distinct roles in different tissues. Such specific expression can be extended to cell-type specific expression as shown in hippocampus. It will be of significance to determine which of these two polysialyltransferases play a dominant role in various tissues and cells.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U82762[GenBank].
We thank Drs. Yasumasa Arai and Rita
Gerardy-Schahn for 12E3 and 735 antibody, Drs. Rick Troy and Frank
Walsh for bacteriophage K1F (endo-N) and pHAPr-1-neo-N-CAM, Dr.
David Smoller for carrying out FISH analysis, Noriko Ohnishi for
preparation of endo-N, Drs. Tsutomu Katsuyama and Tetsuji Moriizumi
for useful discussion, Dr. Edgar Ong for critical reading of the
manuscript, and Susan Greaney and Tomoko Angata for organization of the
manuscript.