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J. Biol. Chem., Vol. 275, Issue 29, 21856-21861, July 21, 2000
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From the Department of Molecular & Cellular Biology, University of
Arizona, Tucson, Arizona 85721 and
Received for publication, April 25, 2000
Mutations that disrupt developmental patterning
in Drosophila have provided considerable information about
growth factor signaling mechanisms. Three genes recently demonstrated
to affect signaling by members of the Wnt, transforming growth
factor- Until recently, the analysis of glycosaminoglycan biosynthesis and
structure has focused on vertebrate tissues and cultured cells. These
studies have produced a wealth of information about the enzymes
required for glycosaminoglycan synthesis and the varied structures of
these polymers in different cell types and tissues (1). However,
glycosaminoglycans are also found in invertebrates, including the fruit
fly, Drosophila melanogaster, and the nematode Caenorhabditis elegans. Recent studies have shown that both
of these genetically tractable organisms make chondroitin and heparan sulfate (2, 3). Drosophila is notable for a structurally complex heparan sulfate, containing the principal sulfated species represented in vertebrates (2). Both Drosophila and C. elegans therefore provide the means to study the genes required
for glycosaminoglycan synthesis in vivo, and the role of
these polymers in developmental patterning.
Genetic screens for mutations in Drosophila affecting growth
factor signaling pathways have revealed, thus far, three genes that
bear homology to genes encoding vertebrate glycosaminoglycan biosynthetic enzymes. sgl (4-6), sfl
(7), and ttv (8), encode proteins with
homology to UDP-glucose dehydrogenase,
N-deacetylase/N-sulfotransferase, and
EXT1,1
respectively. sgl mutations compromise signaling mediated by Wg (4-6), a member of the Wnt family, Dpp (4), a transforming growth
factor- It is now well established that glycosaminoglycans and their associated
proteoglycans are required for signaling mediated by a number of growth
factors that pattern tissues during development. Indeed, defects in a
Drosophila glypican encoded by the dally gene
disrupt both Wg and Dpp signaling in a tissue-selective manner (12-15). The ability of Dally to affect different signaling pathways in distinct cells suggests the hypothesis that the nature of the glycosaminoglycan attached to the protein core influences its biological activity. Structurally diverse forms of heparan sulfate show
tissue-specific distributions (16), indicating that control of
glycosaminoglycan fine structure could well be important in governing
patterning and cell-cell communication. The distinct developmental
defects found in mice bearing a gene trap mutation in heparan
sulfate 2-O- sulfotransferase argues that distinct modifications
of heparan sulfate are indeed crucial for particular patterning events
(17). One way to directly investigate the biological functions of
specific glycosaminoglycan structures in vivo is to examine
patterning in animals bearing mutations in genes affecting distinct
biosynthetic activities. A critical step in this approach is to perform
structural analysis of glycosaminoglycans from mutants defective for
particular genes to establish the molecular changes resulting from the
loss of this biosynthetic activity. In earlier work we reported methods
for structural analysis of glycosaminoglycans in Drosophila
and C. elegans using HPLC separation of disaccharides
generated by lyase digestion (2). We have now applied these procedures
to the detailed analysis of glycosaminoglycans isolated from animals
bearing mutations in three genes proposed to serve roles in
glycosaminoglycan biosynthesis on account of their homology to
vertebrate genes. Based upon the molecular phenotype of these mutants,
we can draw conclusions as to the signaling activities of different
classes of glycosaminoglycans during developmental patterning.
Materials--
The following standard unsaturated disaccharides
from heparan sulfate were purchased from Sigma:
2-acetamido-2-deoxy-4-O-(4-deoxy-O-L-threo-hex-enepyranosyluronic acid)-D-glucose (
The standard unsaturated disaccharides from chondroitin sulfate and
enzymes were purchased from Seikagaku America (Falmouth, MA):
2-acetamido-2-deoxy-3-O-( Determination of Unsaturated Disaccharides by HPLC--
The
determination of unsaturated disaccharides was performed by
fluorometric post-column HPLC as reported previously (2).
Preparation of Glycosaminoglycans from Drosophila--
For the
analysis of sgl, second instar larvae were used on account
of the considerable lethality observed between the second and third
instar stages. Studies of sfl and ttv were
conducted using late third instar larvae, and both second and third
instar larvae of the Oregon-R strain were used as wild-type controls. Approximately 20 mg of wild-type, sgl, sfl, or
ttv homozygous larvae were lyophilized and extracted in 1.0 ml of 0.5% SDS, 0.1 M NaOH, 0.8% NaBH4 as
described previously (2). The resulting crude glycosaminoglycan was
dissolved in 250 µl of 50 mM sodium phosphate buffer (pH
6.0), and applied on a Ultrafree-MC DEAE, which had been equilibrated
with 50 mM sodium phosphate buffer (pH 6.0). The eluted
fractions of 0.15 M and 1.0 M NaCl in the phosphate buffer were collected, desalted with Biomax-5, evaporated, and resuspended in 12 µl of water.
Analysis of Heparan Sulfate in Drosophila--
For the analysis
of Drosophila heparan sulfate, 5 µl of 0.1 M
acetate buffer (pH 7.0) with 10 mM calcium acetate and 10 µl of an aqueous solution containing heparin lyase mixture,
heparinase (1 mIU), heparitinase I (1 mIU), and heparitinase II (1 mIU)
were added to a 5-µl portion of sample solution. The mixture was
incubated at 37 °C for 16 h, and an 8-µl aliquot was loaded
onto the high performance liquid chromatograph. Using known amounts of
standards we have determined that the detection limit of our system is
1.5 ng of heparan sulfate-derived disaccharides.
Analysis of Chondroitin Sulfate in Drosophila--
A 1-µl
portion of the sample solution was diluted to 10 µl with water and
used for the determination of chondroitin sulfate. For chondroitinase
digestion, 4 µl of 0.2 M Tris acetate buffer (pH 8.0) and
4 µl of an aqueous solution containing chondroitinase ABC (20 mIU),
chondroitinase ACII (20 mIU) were added to a 4-µl portion of the
sample solution and incubated at 37 °C for 3 h. An 8-µl
portion of this mixture was loaded onto the high performance liquid
chromatograph. The detection limit for chondroitin sulfate-derived saccharides in our system is 0.5 ng.
Genetic Stocks and Mutant Alleles--
Two different alleles of
sgl were used for our analysis,
sglP1731 and sglA31.
Chromosomes with these mutations were maintained over a Green Fluorescent Protein gene bearing third chromosome balancer, TM3 P[w+, Act-GFP], Ser1. Larvae homozygous for
sfll(3)03844 were employed for the analysis of
sfl function, and maintained over the TM3
balancer as above. tout-velul(2)00681 mutants
used in this study were maintained as a stock over the second
chromosome balancer, CyO P[w+, ubq-GFP]. In all cases, homozygous larvae were identified by the lack of GFP fluorescence detectable under UV illumination in a dissecting microscope.
The analysis of glycosaminoglycans in sgl, sfl, and
ttv larvae consisted of four assays. In the first two, the
levels of both chondroitin and 4-O-sulfated chondroitin
disaccharides were determined by HPLC separation of
chondroitinase-treated material eluted from DEAE membrane under either
low (0-0.15 M NaCl) or high salt (0.15-1.0 M
NaCl) conditions. Similarly, two assays of disaccharides generated by
lyase digestion of heparan sulfate were conducted, one for material
retained on DEAE membrane under low salt conditions (0-0.15 M NaCl), and a second for material that bound to DEAE
membrane at salt concentrations between 0.15 and 1.0 M.
These experiments therefore provided a profile of chondroitin, low
sulfated chondroitin 4-sulfate (Fig. 1,
A and B), N-acetyl heparosan (a
nonsulfated precursor of heparin), and heparan sulfate (Fig.
2, A and B). The
material that elutes prior to the first disaccharide peak for profiles
of both chondroitin sulfate and heparan sulfate-derived disaccharides
(Figs. 1 and 2) is found in enzyme blank controls, and represents other
molecules found in the crude glycosaminoglycan preparation, such as
glycoproteins. These molecules react with the fluorophore,
2-cyanoacetamide, but do not interfere with the analysis of the
glycosaminoglycan-derived disaccharides.
Analysis of Wild-type--
Separation of glycosaminoglycans
released from DEAE membrane with low or high salt washes showed these
polymers can be subdivided into distinct classes. The low salt fraction
of chondroitinase-sensitive polymers, which represent approximately
20% of the total, was comprised of sugarless--
sgl encodes a protein with homology to
bovine UDP-glucose dehydrogenase (4-6), an enzyme required for
generating UDP-glucuronate, the substrate for glucuronate addition to
glycosaminoglycan chains. If sgl were the only gene capable
of providing UDP-glucose dehydrogenase activity, the levels of
chondroitin, chondroitin sulfate, and heparan sulfate would be expected
to be dramatically reduced, but not necessarily eliminated, in
sgl mutant second instar larvae (see below). This prediction
was borne out; we were unable to detect any chondroitin or chondroitin
sulfate in the fraction of glycosaminoglycans from sgl
mutants retained on DEAE under high salt conditions (Fig. 1, Tables I
and III). A trace amount of
sgl, like sfl, and ttv, is expressed
in the ovary and maternal contributions of mRNA and protein to the
oocyte are essential for early embryonic development. Embryos that are
sgl/sgl receive sufficient maternal contributions of
sgl function from their sgl/+ mothers to go
through early development normally and maternally provided activity
typically wanes in late larval and early pupal development. For this
reason, glycosaminoglycans are not expected to be completely absent in
second or third instar larvae homozygous for sgl. We
observed approximately 34- and 12-fold reductions in total
disaccharides derived from chondroitin sulfate and heparan sulfate,
respectively, in sgl mutants (Tables I-III). These findings show that sgl is critical for both chondroitin sulfate and
heparan sulfate biosynthesis, and is likely the only gene providing
UDP-glucose dehydrogenase activity in Drosophila.
sulfateless--
The amino acid sequence of sfl
predicts this gene encodes an
N-deacetylase/N-sulfotransferase. If
sfl does indeed provide this activity in Drosophila,
sfl mutants should retain normal levels and composition profiles
of chondroitin and chondroitin sulfate. Our analysis of sfl
mutants documents that this is indeed the case; sfl mutants
have normal levels of chondroitin and low sulfated chondroitin
4-sulfate chondroitin in both low and high salt DEAE fractions (Fig. 1,
A and B, Table I). sfl mutants did, however, show dramatic changes in their heparan sulfate profiles (Fig.
2, E and F and Table II). First, the five
different forms of sulfated disaccharides detected with our methods
were completely absent from the high salt DEAE fraction obtained form
sfl homozygous larvae (Fig. 2F, Table II). A
trace amount of tout-velu--
Earlier studies showed that ttv, a gene
related to vertebrate EXT1, affects the levels of heparan
sulfate in vivo (2, 9). These finding were consistent with
ttv encoding a heparan sulfate co-polymerase. We have
extended these experiments to determine precisely what
glycosaminoglycans remain in ttv mutant larvae. Chondroitin
sulfate-derived disaccharides are largely unchanged, with a modest
reduction in levels while retaining a wild-type composition in both the
low and high salt fractions (Fig. 1 and Table I). All heparan
sulfate-derived disaccharides, however, showed a marked reduction,
essentially below our detectable limits of 1.5 ng (Fig. 2, G
and H, and Tables II and III). The selective and substantive
effect of ttv on heparan sulfate levels in vivo indicates that ttv is critical for the bulk of heparan
sulfate biosynthesis.
Roles of sgl, sfl, and ttv in Glycosaminoglycan
Biosynthesis--
We have examined the structures of
glycosaminoglycans in animals bearing mutations in genes encoding
proteins with homology to three known glycosaminoglycan biosynthetic
enzymes. In all three cases, the changes in whole animal
glycosaminoglycan profiles are consistent with the
Drosophila gene providing the enzymatic activity predicted
from the relatedness to the vertebrate genes (Table III, Fig.
3).
sgl mutants show dramatic reductions in both chondroitin and
heparan sulfate levels, consistent with a defect in UDP-glucuronate generation catalyzed by a UDP-glucose dehydrogenase. These findings support earlier studies showing that modification of Dally (14) and
Syndecan (4) is altered in sgl mutants. The residual levels of chondroitin and heparan sulfate-derived disaccharides remaining in
sgl mutants most likely results from maternal contributions of wild-type sgl mRNA to the embryo, which provides
sufficient activity for normal embryonic development. The trace amounts
we detect indicate that zygotic sgl function is required for
continued glycosaminoglycan biosynthesis once maternal stores are exhausted.
sfl, a Drosophila gene encoding a protein related
to vertebrate N-deacetylase/N-sulfotransferase,
also had a profound effect on heparan sulfate levels in
vivo. While chondroitin levels and composition were unaffected by
loss of sfl function, sfl mutants showed changes
in heparan sulfate composition without appreciably affecting the total
levels of heparan sulfate. We could not detect any sulfated
disaccharides generated by heparin lyase digestion of
glycosaminoglycans from sfl homozygous larvae. This finding provides in vivo support for earlier work using in
vitro preparations (18) or tissue culture cells (19, 20)
demonstrating that N-deacetylation/N-sulfation is
an early step in heparan sulfate modification required for subsequent
sulfotransferase reactions at the 2-O position of iduronate
or glucuronate, and the 6-O-position of glucosamine.
N-Deacetylase/N-sulfotransferase activity is
likely to be required to provide the template for a variety of later modification steps.
The analysis of ttv reported here extends earlier studies
and documents that heparan sulfate synthesis is significantly
compromised by loss of ttv function. Heparin lyase-sensitive
glycosaminoglycans were reduced to below detectable limits in
ttv mutant larvae. ttv did not, however, effect
the levels or composition of chondroitinase-sensitive glycosaminoglycans. These findings show that ttv, a gene
with the greatest homology to vertebrate EXT1
(8), supports the bulk of heparan sulfate synthesis during
post-embryonic development.
The analysis of glycosaminoglycans in sgl, sfl, and
ttv mutants has shown that the glycosaminoglycan
biosynthetic apparatus is largely conserved between
Drosophila and vertebrates. The structural forms of
chondroitin and heparan sulfate represented in Drosophila are also those found in vertebrate species. In addition, the core proteins for several families of proteoglycans are found in
Drosophila, including glypican (13) and syndecan (21). These
findings demonstrate the utility of Drosophila as a model
organism for studying the biosynthesis and function of
glycosaminoglycans and proteoglycans in vivo.
Glycosaminoglycans in Developmental Patterning and Growth Factor
Signaling--
Our analysis of sgl, sfl, and ttv
allows us to make some conclusions concerning the functions of various
glycosaminoglycan forms in growth factor signaling and morphogenesis.
Of these three mutations, sgl and sfl would
appear to have the broadest effects on signaling, compromising both
wg and FGFR-directed events. Furthermore, there is good
evidence that sgl is required for dpp signaling in imaginal
tissues (4, 22). sfl apparently is also required for normal
Hh signaling in the developing wing. While it is not known if
sgl and sfl influence Wg, Dpp, FGF, and Hh
signaling equally, their comparable participation in Wg and FGF
signaling suggests that loss of both chondroitin and heparan sulfate in sgl mutants produces no more deleterious effect than a
failure to add sulfate modifications to heparan sulfate. It would seem therefore, that at least for FGF and Wg signaling, heparan sulfate is
the critical glycosaminoglycan in vivo.
In contrast to the multiple growth factor pathways affected by
sgl and sfl, ttv selectively
influences Hh signaling, leaving wg and FGFR-mediated patterning
untouched in both the embryo and in the imaginal discs (8, 9). The
large reductions in heparan sulfate levels that accompany loss of
ttv function might lead one to predict that ttv
would seriously compromise signaling mediated by several growth factors
known to require sulfated heparan sulfate, Wg and FGF in particular.
Yet this is not the case. In embryos lacking both maternal and
embryonically derived Ttv activity, FGFR and Wg signaling remain (9).
Several explanations for the selective participation of ttv
in Hh signaling are possible in light of these findings. First, we have
examined glycosaminoglycans in larvae, and the studies where
ttv function has been completely removed were primarily performed using embryos. It is possible that there are higher levels of
heparan sulfate in ttv mutant embryos compared with larvae,
presumably derived from other EXT-related genes that could provide
co-polymerase activity. Second, the experiments looking at
ttv function in larvae made use of methods to induce
recombination events in ttv/+ animals midway through
development that produce clones of ttv/ttv cells. Sufficient
Ttv may remain in these clones to provide significant levels of heparan
sulfate co-polymerase activity, levels sufficient for Wg and FGF
signaling, but not for Hh. ttv mutants may also contain
small amounts of specific proteoglycans that are heparan
sulfate-modified normally and permit normal FGF and Wg signaling (9).
This explanation would require Ttv to have core protein selectivity,
placing heparan sulfate chains on a distinct set of proteoglycans.
Finally, it is possible that in the absence of any appreciable heparan
sulfate co-polymerase activity, proteoglycan protein cores are modified
with chondroitin sulfate, and that this sugar polymer is capable of
supporting Wg and FGF signaling, but not Hh signaling or transport. In
this scenario, sfl mutations have such a broad affect
because N-acetyl heparosan chains are added to their normal
protein cores, but do not function because of their lack of sulfation.
The presence of heparan chains would preclude their substitution with
chondroitin sulfate, preventing rescue of proteoglycan function in Wg
and FGF signaling by chondroitin sulfate modification.
*
This work was supported by National Institutes of Health
Grant GM-54832 and the March of Dimes (to S. B. S.), and
National Institutes of Health Grant GM-25243 (to S. Ward) provided for shared equipment used in this study.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. Tel.: 520-621-8663;
Fax: 520-621-3709; E-mail: selleck@u.arizona.edu.
Published, JBC Papers in Press, May 9, 2000, DOI 10.1074/jbc.M003540200
The abbreviations used are:
EXT1, Exostoses 1;
sgl, sugarless;
sfl, sulfateless;
ttv, tout-velu;
dally, division abnormally delayed;
Wg,
wingless;
Dpp, decapentaplegic;
FGFR, fibroblast growth factor
receptor;
Hh, hedgehog;
HPLC, high performance liquid chromatography;
GFP, green fluorescent protein;
PAPS, adenosine 3'-phosphate
5'-phosphosulfate.
Structural Analysis of Glycosaminoglycans in Animals Bearing
Mutations in sugarless, sulfateless, and
tout-velu
DROSOPHILA HOMOLOGUES OF VERTEBRATE GENES ENCODING
GLYCOSAMINOGLYCAN BIOSYNTHETIC ENZYMES*
, The Faculty of
Pharmaceutical Sciences, Chiba University, 1-33 Yayoi, Inage-ku,
Chiba 263-8522, Japan
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
, Hedgehog, and fibroblast growth factor families in
Drosophila encode proteins with homology to vertebrate
enzymes involved in glycosaminoglycan synthesis. We report here the
biochemical characterization of glycosaminoglycans in
Drosophila bearing mutations in sugarless, sulfateless, and tout-velu. We find that mutations in
sugarless, which encodes a protein with homology to
UDP-glucose dehydrogenase, compromise the synthesis of both chondroitin
and heparan sulfate, as would be predicted from a defect in
UDP-glucuronate production. Defects in sulfateless, a
gene encoding a protein with similarity to vertebrate
N-deacetylase/N-sulfotransferases, do not
affect chondroitin sulfate levels or composition but
dramatically alter the composition of heparin lyase-released
disaccharides. N-, 6-O-, and
2-O-sulfated disaccharides are absent and replaced
entirely with an unsulfated disaccharide. A mutation in
tout-velu, a gene related to the vertebrate Exostoses 1 heparan sulfate co-polymerase, likewise does not affect chondroitin
sulfate synthesis but reduces all forms of heparan sulfate to below the
limit of detection. These findings show that sugarless,
sulfateless, and tout-velu affect
glycosaminoglycan biosynthesis and demonstrate the utility of
Drosophila as a model organism for studying the function
and biosynthesis of glycosaminoglycans in vivo.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
/bone morphogenetic protein-related protein, and the FGF
receptors breathless and branchless (7).
sfl likewise affects Wg, Hh, and FGFR signaling (7, 9).
ttv is unique among these three genes in that Hh signaling
is selectively compromised, with Wg-directed events intact in
ttv embryos and third instar larvae (9). Analysis of the
vertebrate homologue of ttv, EXT1, has shown that
EXT1 encodes a heparan sulfate co-polymerase (10, 11).
Recent studies of Drosophila ttv mutants have provided two
lines of evidence that Ttv is also a heparan sulfate co-polymerase. First, analysis of glycosaminoglycans from ttv mutant larvae
revealed a dramatic reduction in the levels of heparan sulfate but not chondroitin sulfate (2). Second, immunohistochemical staining with an
antibody that recognizes an epitope of heparan sulfate generated by
cleavage with heparin lyase is significantly reduced in embryos lacking
both maternal and zygotic ttv function (9).
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
UA-GlcNAc),
2-deoxy-2-sulfamide-4-O-(4-deoxy-
-L-threo-hex-enepyranosyluronic acid)-D-glucose (UA-GlcNS),
2-acetamido-2-deoxy-4-O-(4-deoxy--L-threo-hex-enepyranosyluronic acid)-6-O-sulfo-D-glucose (UA-GlcNAc6S),
2-acetamido-2-deoxy-4-O-(4-deoxy-2-O-sulfo-D-L-threo-hex-enepyranosyluronic acid)-D-glucose (UA2S-GlcNAc),
2-deoxy-2-sulfamide-4-O-(4-deoxy-2-O-sulfo--L-threo-hex-enepyranosyluronic acid)-6-O-sulfo-D-glucose(UA-GlcNS6S),
2-deoxy-2-sulfamide-4-O-(4-deoxy-2-O-sulfo--L-threo-hex-enepyranosyluronic acid)-D-glucose (UA2S-GlcNS),
2-acetamido-2-deoxy-4-O-(4-deoxy-2-O-sulfo--L-threo-hex-enepyranosyluronic acid)-6-O-sulfo-D-glucose (UA2S-GlcNAc6S),
and
2-deoxy-2-sulfamide-4-O-(4-deoxy-2-O-sulfo--L-threo-hex-enepyranosyluronic acid)-6-O-sulfo-D-glucose(UA2S-GlcNS6S).
-D-gluco-4-enepyranosyluronic
acid)-D-galactose (Di-0S),
2-acetamido-2-deoxy-3-O-(-D-gluco-4-enepyranosyluronic acid)-4-O-sulfo-D-galactose (Di-4S),
chondroitinase ABC (EC 4.2.2.4), chondroitinase ACII (EC 4.2.2.5),
heparinase (EC 4.2.2.7), heparitinase I (EC 4.2.2.8), and heparitinase
II. Ultrafree-MC DEAE and Biomax-5 (5000 NMWL) were obtained from
Millipore Corp. (Bedford, MA). All other chemicals used were of
analytical reagent grade.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (19K):
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Fig. 1.
Typical chromatograms of unsaturated
disaccharides from chondroitin sulfate in wild-type, sgl,
sfl, and ttv mutants. A and
C, 0-0.15 M NaCl fraction; B and D, 0.15-1.0
M fraction. Peaks: 1, Di-0S; 2,
Di-4S. Chondroitin sulfate-derived disaccharides are essentially
unaffected in sfl and ttv, but are reduced in
sgl mutants (see Tables I and III).
View larger version (19K):
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Fig. 2.
Typical chromatograms of unsaturated
disaccharides from heparan sulfate in wild-type sgl, sfl,
and ttv mutants. A, C, E, and
G, 0-0.15 M NaCl fraction; B, D, F,
and H, 0.15-1.0 M fraction. Peaks:
1, UA-GlcNAc; 2, UA-GlcNS; 3,
UA-GlcNAc6S; 4, UA-GlcNS6S; 5,
UA2S-GlcNS; 6, UA2S-GlcNS6S. sgl
compromises the levels of all heparan sulfate-derived disaccharides,
whereas sfl mutations block the synthesis of all sulfated
disaccharide species without altering appreciably the total amount of
heparan sulfate-derived disaccharide (note the increased levels of
UA-GlcNAc in the low salt fraction, E, and see Tables II
and III). ttv mutations reduce the levels of all heparan
sulfate-derived disaccharides to below detectable limits (G
and H, see also Tables II and III).
Di-OS only, whereas the high
salt-released fraction showed a mixture of Di-OS and Di-4S (Fig.
1, Table I). Likewise, distinct classes
of heparan sulfate polymers were found in the low and high salt DEAE
fractions (Fig. 2, Table II).
Approximately 10% of the heparin lyase-sensitive material was found in
the low salt fraction and it contained only UA-GlcNAc. The high salt fraction was a complex mixture of disaccharide species, dominated by
mono-, di-, and trisulfate forms (all sulfated forms, 67%). These
profiles of wild-type glycosaminoglycans, done in parallel with the
analysis of sgl, sfl, and ttv mutants, provided a
basis for determining the effects of these genes on glycosaminoglycan biosynthesis.
Comparison of chondroitin sulfates from wild-type and mutant Drosophila
larvae
Comparison of heparan sulfates from wild-type and mutant Drosophila
larvae
Di-OS was detected in
chondroitinase-sensitive glycosaminoglycans from sgl larvae
that bound to DEAE under low salt conditions (Fig. 1C).
sgl mutations also had a profound effect on heparan sulfate biosynthesis. Trace amounts of UA-GlcNAc were found only in the low
salt preparation (Fig. 2C, Tables II and III).
UA-GlcNAc was found in the high salt fraction from
sfl mutants, although much reduced compared with wild-type
larvae. Second, there was a large increase in the levels of
UA-GlcNAc in the low salt DEAE fraction of sfl mutants
compared with wild-type (Fig. 2E) and this disaccharide represents all the material derived by exhaustive heparin lyase digestion of glycosaminoglycans from this mutant (Table
III). It is important to note that the
total level of heparan sulfate-derived disaccharide from sfl
larvae is nearly the same as wild-type (12.3 versus 13.9 ng/mg for sfl and wild-type, respectively), indicating that
differences in recovery do not account for the changes in composition
we observe. These findings show that sfl: 1) affects heparan
sulfate synthesis and not chondroitin or chondroitin sulfate generation, 2) is required for the sulfation at the
N-position of GlcNAc, the 2-O-position of either
glucuronic or iduronic acid, and the 6-O-position of GlcNAc
and GlcNS; and 3) results in the accumulation of N-acetyl
heparosan, a nonsulfated precursor of heparin, at the expense of
sulfated forms of disaccharides.
Summary of glycosaminoglycan levels and disaccharide forms represented
in wild-type and mutant larvae
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (24K):
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Fig. 3.
Role of sgl, sfl,
and ttv in the biosynthesis of proteoglycans in
Drosophila. Glycosaminoglycan synthesis is
initiated by addition of xylose to specific serine residues of the
protein core, with UDP-xylose serving as the sugar donor. The
nucleotide-sugar donors are listed on the left of the
figure, with the sequence of synthesis for the tetrasaccharide linker
and glycosaminoglycan chain going from top to
bottom. After the tetrasaccharide linker is made
(GlcA-Gal-Gal-Xyl-serine), heparan sulfate synthesis requires addition
of GlcNAc, whereas chondroitin proceeds with GalNAc addition. Our data
support Sgl as a UDP-glucose dehydrogenase, the enzyme that catalyzes
the conversion of UDP-glucose to UDP-glucuronate, a nucleotide-sugar
donor required for all glycosaminoglycan biosynthesis. Ttv is related
to EXT1, a heparan sulfate co-polymerase that adds alternatively GlcNAc
and GlcA to the growing polymer. The biochemical defects of
ttv mutants are consistent with ttv encoding the
principal heparan sulfate co-polymerase in Drosophila.
Finally, our data support the assignment of Sfl as an
N-deacetylase/N-sulfotransferase required for
replacing the acetyl group on GlcNAc with a sulfate. Loss of
sfl function also prevents 2-O-sulfation of
uronic acid and 6-O-sulfation of glucosamine, suggesting
that N-sulfation is essential for subsequent modification
steps in Drosophila. Abbreviations: Xyl, xylose;
Gal, galactose; GlcA, glucuronic acid;
GalNAc, N-acetylgalactosamine.
FOOTNOTES
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1.
David, G.,
and Bernfield, M.
(1998)
Matrix Biol.
17,
461-463
2.
Toyoda, H.,
Kinoshita-Toyoda, A.,
and Selleck, S. B.
(2000)
J. Biol. Chem.
275,
2269-2275
3.
Yamada, S.,
Van Die, I.,
Van den Eijnden, D. H.,
Yokota, A.,
Kitagawa, H.,
and Sugahara, K.
(1999)
FEBS Lett.
459,
327-331
4.
Haerry, T. E.,
Heslip, T. R.,
Marsh, J. L.,
and O'Connor, M. B.
(1997)
Development
124,
3055-3064
5.
Binari, R. C.,
Staveley, B. E.,
Johnson, W. A.,
Godavarti, R.,
Sasisekharan, R.,
and Manoukian, A. S.
(1997)
Development
124,
2623-2632
6.
Häcker, U.,
Lin, X.,
and Perrimon, N.
(1997)
Development
124,
3565-3573
7.
Lin, X.,
Buff, E. M.,
Perrimon, N.,
and Michelson, A. M.
(1999)
Development
126,
3715-3723
8.
Bellaiche, Y.,
The, I.,
and Perrimon, N.
(1998)
Nature
394,
85-88
9.
The, I.,
Bellaiche, Y.,
and Perrimon, N.
(1999)
Mol. Cell
4,
633-639
10.
Lind, T.,
Tufaro, F.,
McCormick, C.,
Lindahl, U.,
and Lidholt, K.
(1998)
J. Biol. Chem.
273,
26265-26268
11.
McCormick, C.,
Leduc, Y.,
Martindale, D.,
Mattison, K.,
Esford, L. E.,
Dyer, A. P.,
and Tufaro, F.
(1998)
Nat. Genet.
19,
158-161
12.
Jackson, S. M.,
Nakato, H.,
Sugiura, M.,
Jannuzi, A.,
Oakes, R.,
Kaluza, V.,
Golden, C.,
and Selleck, S. B.
(1997)
Development
124,
4113-4120
13.
Nakato, H.,
Futch, T. A.,
and Selleck, S. B.
(1995)
Development
121,
3687-3702
14.
Tsuda, M.,
Kamimura, K.,
Nakato, H.,
Archer, M.,
Staatz, W.,
Fox, B.,
Humphrey, M.,
Olson, S.,
Futch, T.,
Kaluza, V.,
Siegfried, E.,
Stam, L.,
and Selleck, S. B.
(1999)
Nature
400,
276-280
15.
Lin, X.,
and Perrimon, N.
(1999)
Nature
400,
281-284
16.
Maccarana, M.,
Sakura, Y.,
Tawada, A.,
Yoshida, K.,
and Lindahl, U.
(1996)
J. Biol. Chem.
271,
17804-17010
17.
Bullock, S. L.,
Fletcher, J. M.,
Beddington, R. S.,
and Wilson, V. A.
(1998)
Genes Dev.
12,
1894-1906
18.
Kusche, M.,
Oscarsson, L. G.,
Reynertson, R.,
Roden, L.,
and Lindahl, U.
(1991)
J. Biol. Chem.
266,
7400-7409
19.
Bame, K. J.,
and Esko, J. D.
(1989)
J. Biol. Chem.
264,
8059-8065
20.
Bame, K. J.,
Lidholt, K.,
Lindahl, U.,
and Esko, J. D.
(1991)
J. Biol. Chem.
266,
10287-10293
21.
Spring, J.,
Paine-Saunders, S. E.,
Hynes, R. O.,
and Bernfield, M.
(1994)
Proc. Nat. Acad. Sci. U. S. A.
91,
3334-3338
22.
O'Connor, M.,
and Haerry, T. E.
(1999)
in
Cell Surface Proteoglycans in Signalling and Development
(Lander, A.
, Nakato, H.
, Selleck, S. B.
, Turnbull, J. E.
, and Coath, C., eds), Vol. VI
, pp. 169-176, Human Frontier Science Program, Strasbourg
Copyright © 2000 by The American Society for Biochemistry and Molecular Biology, Inc.
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