From the Department of Biochemistry and Molecular Biology, Mayo Clinic Scottsdale, Scottsdale, Arizona 85259
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ABSTRACT |
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The three mammalian hyaluronan synthase (HAS) genes and the related Xenopus laevis gene, DG42, belong to a larger evolutionarily conserved vertebrate HAS gene family. We have characterized additional vertebrate HAS genes from chicken (chas2 and chas3) and Xenopus (xhas2, xhas3, and a unique Xenopus HAS-related sequence, xHAS-rs). Genomic structure analyses demonstrated that all vertebrate HAS genes share at least one exon-intron boundary, suggesting that they evolved from a common ancestral gene. Furthermore, the Has2 and Has3 genes are identical in structure, suggesting that they arose by a gene duplication event early in vertebrate evolution. Significantly, similarities in the genomic structures of the mouse Has1 and Xenopus DG42 genes strongly suggest that they are orthologues. Northern analyses revealed a similar temporal expression pattern of HAS genes in developing mouse and Xenopus embryos. Expression of mouse Has2, Has3, and Xenopus Has1 (DG42) led to hyaluronan biosynthesis in transfected mammalian cells. However, only mouse Has2 and Has3 expressing cells formed significant hyaluronan-dependent pericellular coats in culture, implying both functional similarities and differences among vertebrate HAS enzymes. We propose that vertebrate hyaluronan biosynthesis is regulated by a comparatively ancient gene family that has arisen by sequential gene duplication and divergence.
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INTRODUCTION |
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Simple linear carbohydrate polymers make up the largest biomass on the Earth. These polymers include cellulose, chitin, and arguably their vertebrate equivalent, hyaluronan (HA).1 All of these polymers play protective or supporting roles in the organisms in which they are synthesized; cellulose makes up the plant cell wall, chitin makes up fungal cell walls and arthropod exoskeletons, and hyaluronan is an important component of skin, cartilage, and connective tissue. The hyaluronan capsule synthesized by group A streptococci also plays a protective role in this bacterium, shielding the organism from the host's immune system (1-3). In addition to protective and supporting roles based upon physicochemical properties, simple carbohydrate polymers can act as signaling molecules. For example, in leguminous plants short lipochito-oligosaccharides produced by rhizobial species signal the formation of the specialized root nodule structure (4, 5). Moreover, in vertebrates hyaluronan can influence cell behavior including cell migration, proliferation, and differentiation through interactions with specific cell-surface HA receptors such as CD44 and RHAMM (6-9).
Recent studies are beginning to identify the genes encoding the enzymes
that are responsible for the biosynthesis of these polymers (10-19).
We have focused our efforts on the identification and study of putative
eukaryotic HA synthases (13-18). HA is a high molecular weight
glycosaminoglycan composed of a linear array of
D-glucuronic
acid1
3N-acetylglucosamine
1
4 disaccharide
units. HA is synthesized at the inner face of the plasma membrane, and thus the enzymes responsible for HA biosynthesis are predicted to be
plasma membrane proteins (20-23). We and others (13-18) have recently
characterized three related mammalian genes (HAS1, HAS2, and HAS3)
encoding putative plasma membrane hyaluronan synthases. The three gene
products share 55-71% sequence identity. In addition, they display
sequence homology with the Streptococcus pyogenes HA
synthase, HasA, to the developmentally regulated Xenopus
laevis DG42 protein and to other
-glycosaminyltransferases such
as the rhizobial NodC proteins, yeast chitin synthases, and a recently reported family of putative plant cellulose synthases (18). Expression
of any one mammalian HAS gene leads to HA biosynthesis by transfected
mammalian cells, suggesting a critical role for these enzymes in the HA
biosynthetic pathway. The three mammalian HAS genes are localized on
separate autosomes (24), supporting the idea that this gene family may
have arisen through comparatively ancient gene duplication events.
A controversy has emerged regarding the true biological function of the Xenopus DG42 protein (25). DG42 has been described as both a putative chito-oligosaccharide synthase (26, 27) and as a bona fide hyaluronan synthase (28, 29). Furthermore, some of these studies have proposed that there may be functional overlap in these two biosynthetic pathways, with chitin oligosaccharides possibly acting as primers that are required for and the limiting factor for hyaluronan biosynthesis (25, 27).
In this paper, we report the results of studies designed to elucidate the relationships between HAS family members and Xenopus DG42. These studies demonstrate that the Xenopus DG42 gene is a member of a larger vertebrate gene family that includes the mammalian HAS genes. The data presented also show that the vertebrate hyaluronan synthases are differentially expressed and have related but distinct enzymatic properties.
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EXPERIMENTAL PROCEDURES |
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cDNA and Genomic Cloning-- Degenerate PCR primers specific for HAS genes (16, 18) were used to amplify HAS gene fragments from genomic DNAs of different animal species by the polymerase chain reaction (PCR). Genomic DNA samples included human (T47D mammary carcinoma cell line), 129Sv/J mouse, chicken (Gallus gallus), and X. laevis genomic DNA. HAS gene-specific PCR fragments were amplified as described previously (18), and products were gel-purified and ligated directly into a pBluescript KSII+ based T-vector (30) for subsequent analyses.
A X. laevis Has1 (DG42) open reading frame (ORF) was amplified by reverse transcriptase-PCR from X. laevis embryonic stage 12 total RNA (kindly provided by Dr. Douglas DeSimone, University of Virginia, Charlottesville) with the following primers: forward, 5Northern Analyses-- The expression of mouse, human, and Xenopus hyaluronan synthase genes were examined by Northern analysis. Northern blots of staged mouse embryo and human adult tissue poly(A)+ RNAs (CLONTECH) were hybridized sequentially with radiolabeled portions of mouse or human HAS cDNAs. 32P-Labeled probes were prepared by random priming (34). Total RNAs prepared from staged X. laevis embryos were kindly provided by Dr. Douglas DeSimone of the University of Virginia, Charlottesville. Approximately 20 µg of total RNA samples were separated by formaldehyde-agarose gel electrophoresis and transferred to Hybond N+ membranes (Amersham Corp.). Membranes were stained with methylene blue (35) prior to prehybridization to visualize ribosomal RNAs to determine sample loading and efficiency of transfer. Membranes were sequentially hybridized with partial cDNA probes representative of Xenopus Has1 (DG42), Xenopus Has2, Xenopus Has3, and Xenopus HAS-rs. Membranes were hybridized in 0.2 M sodium phosphate, pH 7.2, 7% SDS, 1 mM EDTA, pH 8.0, overnight at 65 °C, and subsequently washed three times at 65 °C for 30 min in 40 mM sodium phosphate, pH 7.2, and 1% SDS, and exposed to BioMax MR (Eastman Kodak) autoradiographic film. Probes were stripped from membranes through two 15-min washes in boiling 0.5% SDS prior to rehybridization.
Creation of HAS Expression Vectors--
Mammalian expression
vectors containing the ORFs of mouse Has2 and mouse Has3 have been
described previously (16, 18). Clones representing the ORFs of mouse
Has1, Xenopus Has1 (DG42), and Xenopus HAS-rs
were created from cDNA or plasmid templates using PCR and the
following primer pairs: mouse HAS1 forward, 5-GGCCCGGGGCCATGGGACAGGACATGCCAAAGCC-3
and reverse,
5
-GGCCCGGGTGATACTTGGACACGGTAACCACCGCTCCG-3
, corresponding to
nucleotides 46 to 71 and 1800 to 1771, respectively (13);
Xenopus Has1 (DG42) (described above); Xenopus
HAS-rs forward, 5
-GGCCCGGGACCATGGAAAATACAACAGATCCAGAG-3
and reverse, 5
-GGCCCGGGTCAGACAAGAAGAGAAACAGATAGAC-3
, corresponding to
nucleotides 50 to 75 and 1803 to 1778, respectively. Products were
amplified through 20 cycles of 94 °C 10 s, 65 °C 30 s,
72 °C 2 min, followed by a final extension step of 72 °C for 10 min. 5
- and 3
-UTRs were not included in any of the expression vectors
to avoid potential adverse effects on message stability and
translational efficiency. Amplified products of the expected size were
gel-purified and ligated directly into the pBluescript KSII+ T-vector.
Inserts were sequenced in their entirety to ensure that no PCR-induced errors had been introduced. Clones determined to be correct with respect to previously published sequences were subcloned into the
polylinker of the pCIneo expression vector (Promega Corp) by virtue of
flanking restriction sites within the polylinker of pBluescript KSII+
(mouse Has1 and Xenopus Has1 (DG42)) or by virtue of
restriction sites incorporated within the PCR primers (mouse Has2,
Has3, and Xenopus HAS-rs).
HA Coat Assays and in Vitro HA Synthase Assays-- COS-1 cells and 293 (transformed human embryonal kidney (36)) cells were transfected with HAS gene expression vectors and assayed for the presence of HA-dependent pericellular coats as described previously (16). Crude cell membranes were prepared from transfected COS-1 cells growing in 15-cm diameter tissue culture plates (18). Final membrane pellets were resuspended in 50 µl of LB+/15-cm tissue culture plate. Protein content of crude membrane preparations was determined using a BCA assay (Pierce). Briefly, HA synthase assays were performed as described previously (18) using 50 µg of crude membrane protein per reaction. Reactions were allowed to proceed at 37 °C for 2 h and were stopped by boiling for 10 min. The pH of the reactions was lowered to pH 5.0 by the addition of 20 mM sodium acetate, pH 4.0. The reactions were split in two, and 1 TRU (turbidity reducing unit) of Streptomyces hyalurolyticus hyaluronidase (CALBIOCHEM) (resuspended at 100 TRU/ml) was added to half of the tubes. All tubes were subsequently incubated overnight at 60 °C. Following this incubation, SDS was added to each sample to a final concentration of 1%. The samples were boiled for 5 min and separated overnight by descending paper chromatography (37). Radioactivity remaining at the origin was counted by liquid scintillation counting. The amount of radiolabeled product formed was calculated based upon the specific activity of the UDP-[14C]GlcUA, the amount of cold UDP-GlcUA and radiolabeled UDP-GlcUA used, and 14C counting efficiency of >95%.
Agarose Gel Electrophoresis of in Vitro Synthesized
Hyaluronan--
To estimate the molecular mass of the in
vitro synthesized products formed through the assays described
above, products were subjected to agarose gel electrophoresis. Briefly,
hyaluronidase treated or untreated reactions were loaded on 1% agarose
gels and run alongside HindIII and 1-kb ladder molecular
weight markers (Life Technologies, Inc.). Gels were stained by ethidium
bromide, photographed, dried overnight at room temperature under
vacuum, and exposed to BioMax MR autoradiographic film for 4-8 days at room temperature. The molecular mass of products was estimated based
upon distance migrated in relation to the molecular weight markers,
with reference to previously published data (38).
Polyclonal Antisera Production and Purification-- To generate HAS-specific antisera, three predicted antigenic regions of mouse Has2 were selected, and synthetic peptides were made. These peptides had the following sequences: peptide 1, WKNNFHEKGPGETEESHKESSQH (amino acids 148-170 (16)); peptide 2, EDWYNQEFMGNQCSFGDDRHLTNR (amino acids 297-320 (16)); and peptide 3, CGRRKKGQQYDMVLDV (amino acids 537-552 (16)). A C-terminal cysteine was added to peptides 1 and 2 to facilitate conjugation to keyhole limpet hemocyanin and bovine serum albumin using a heterobifunctional cross-linker. Two New Zealand White rabbits were immunized (Cocalico Biologicals, Reamstown, PA) with each peptide-keyhole limpet hemocyanin conjugate. Antisera were characterized by enzyme-linked immunosorbent assay, and after boosting, specific antibodies were purified against cognate peptide conjugated to Sulfolink® coupling gel (Pierce) according to the manufacturer's recommendations. In addition to the antisera raised against mouse Has2 peptides, a previously characterized rabbit polyclonal antiserum raised against an N-terminal portion of the X. laevis Has1 (DG42) protein (31) was kindly provided by Dr. Igor Dawid, Laboratory of Molecular Genetics, NICHD. This antisera was partially affinity purified by passage through a protein A-agarose column, followed by elution of the IgG fraction. The protein content of purified antibodies was determined by BCA assay.
Immunoblotting-- Crude cell membrane preparations from transfected COS-1 cells were analyzed by immunoblotting with HAS-reactive antisera. SDS-polyacrylamide gel electrophoresis reducing sample buffer was added to 8 µg samples of crude membrane preparations, and samples were heated at 37 °C for 5 min prior to separation on 5% stacking, 7.5% resolving polyacrylamide gels. After electrophoresis, proteins were electrotransferred to Hybond-C membranes (Amersham Corp.). Membranes were blocked overnight in 5% non-fat dry milk in TBST (10 mM Tris-HCl, pH 8.0, 150 mM NaCl, 0.05% Tween 20) at 4 °C and then washed three times in TBST for 5 min at room temperature. Primary antibodies were diluted in TBST to the following final concentrations: anti-mHas2 peptide 1 (MC285), 1 µg/ml; anti-mHas2 peptide 2 (MC287), 2 µg/ml; anti-xHas1 (DG42) N terminus, 5 µg/ml. The secondary antibody was a horseradish peroxidase-conjugated donkey anti-rabbit IgG (Amersham Corp.) used at a dilution of 1:5000 in TBST. Membranes were incubated with diluted primary antibodies for 3 h at 37 °C and then washed three times in TBST for 5 min at room temperature. Membranes were incubated in diluted secondary antibody for 1 h at 37 °C and then washed three times in TBST for 20 min at room temperature. Immune complexes were detected using enhanced chemiluminescence under conditions recommended by the manufacturer (Amersham Corp.).
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RESULTS |
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Degenerate PCR Cloning of Vertebrate HAS Gene Fragments-- PCR using genomic DNA and degenerate HAS gene oligonucleotides was used to identify fragments of HAS genes from several vertebrate species. Specific fragments were amplified from human (Homo sapiens), mouse (Mus musculus domesticus), chicken (G. gallus), and the African clawed toad (X. laevis). Sequence analysis of cloned PCR fragments indicated that the human and mouse HAS fragments represented the HAS1, HAS2, and HAS3 genes. In the chicken, only clones representative of chas2 and chas3 were obtained. In X. laevis, clones representative of xhas1 (DG42), xhas2, xhas3, and a previously unidentified HAS-related sequence, designated xHAS-rs, were obtained. Extensive sequence conservation between species permitted the classification of HAS clones obtained from each animal (Fig. 1). In addition, sequence alignment indicated that a fragment of a zebrafish (Danio rerio) HAS gene previously reported as zebrafish DG42 (27) is clearly a fragment of zebrafish Has2 (zhas2).
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cDNA Cloning of a Xenopus HAS-related Sequence
(xHAS-rs)--
To characterize further the HAS-related sequence
(xHAS-rs) in Xenopus, 5 and 3
RACE (rapid
amplification of cDNA ends) reactions were performed using
Xenopus stage 12 total RNA. Overlapping products were
directly cloned and sequenced. These clones spanned a total of 2.2 kb
and contained an ORF of 1749 base pairs predicting a protein of 583 amino acids (Fig. 2). The amino acid
sequence for Xenopus HAS-rs was most similar to
Xenopus DG42 (now designated xHas1) (65% identity) and
shared approximately 49% identity with the three mammalian HAS
proteins (Fig. 3A) and 25%
identity to Streptococcus HasA. Significantly, two residues
critical for the activity of yeast chitin synthase 2 (39) and conserved
among all other HAS proteins, chitin synthases and cellulose synthases, are not conserved in xHAS-rs; these include an aspartate (Asp) residue
in the motif DSDT, which is NSDI in xHAS-rs, and an arginine (Arg)
residue in the motif QXXRW, which is QQTPW in xHAS-rs (Fig. 3B). This might suggest that Xenopus HAS-rs is
inactive as a processive glycosyltransferase (40) or may have diverged
significantly to become functionally distinct from other HAS family
members.
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Genomic Structure Analysis of Vertebrate HAS Genes-- The genomic structure for Xenopus DG42 (now designated xhas1) has been previously reported (31). Similarly, we have previously reported the locations of exon-intron boundaries within the mouse Has3 gene (18). We determined the complete genomic structures for mouse Has1, Has2, Has3, and Xenopus HAS-rs to understand potential evolutionary relationships among all known vertebrate HAS genes. Restriction maps were derived for each gene, and the locations of all exon-intron boundaries were determined (Fig. 4 and Table I). Mouse Has2 represents the largest of the HAS genes, spanning approximately 30 kb. Xenopus has1 (DG42) represents the smallest of the HAS genes, spanning only 4 kb. The mouse Has1, Xenopus has1 (DG42), and Xenopus HAS-rs genes are made up of 5 exons, whereas the mouse Has2 and Has3 genes are made up of only 4 exons.
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Northern Analysis of Vertebrate HAS Expression-- We have previously reported the temporal expression of mouse Has2 and Has3 in the developing mouse embryo (16, 18). These Northern studies were extended by analyzing the expression of mouse Has1 in staged mouse embryos and the expression of Xenopus Has1 (DG42), xHas2, xHas3, and xHAS-rs in staged Xenopus embryos (Fig. 5A). In addition, we analyzed the expression of human HAS1, HAS2, and HAS3 in a panel of poly(A)+ RNAs isolated from adult tissues (Fig. 5B).
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Functional Assays-- A simple but classical particle exclusion assay (43) was used to investigate the ability of vertebrate HAS enzymes to generate a HA-dependent pericellular coat in cultured mammalian cells. These assays demonstrated that only Has2 and Has3 expression led to the formation of significant pericellular coats that were specifically destroyed by the action of Streptomyces hyaluronidase in both COS-1 (Fig. 6, top) and 293 cells (data not shown).
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Characterization of HAS-reactive Antisera by Immunoblotting-- Rabbit polyclonal antisera were raised against Has2-derived synthetic peptides to create reagents to detect HAS proteins. Immunoblotting revealed that antisera raised against peptide 1 (MC285) were specific for mouse Has2 (Fig. 7). This antisera detected a major 52-kDa species and several smaller species only in crude membrane preparations of mouse Has2-transfected COS-1 cells. Antisera raised against peptide 3 (MC 288) were also specific for mouse Has2 (data not shown). In contrast, antisera raised against peptide 2 (MC287) detected all HAS proteins, including Xenopus Has1 (DG42) but excluding Xenopus HAS-rs (Fig. 7). Proteins of the following estimated molecular masses were detected: Xenopus Has1 (DG42), 60 kDa; mouse Has1, 58 kDa; mouse Has2, 52 kDa; and mouse Has3, 52 kDa. Proteins were expressed at similar levels. Under our conditions, all vertebrate HAS enzymes migrated faster than their predicted molecular masses. A similar phenomenon has been previously reported for S. pyogenes HasA (12) and Xenopus Has1 (DG42).2 Cross-reacting proteins were not detected in samples prepared from xHAS-rs or pCIneo (control)-transfected cells. We assume that the observed lack of cross-reactivity with xHAS-rs is sequence-based and not due to lack of expression of this protein in COS-1 cells. Significantly, an antiserum raised against an N-terminal portion of Xenopus Has1 (DG42) (31) was completely specific for Xenopus Has1 (DG42), detecting an identical protein to that identified by MC287 only in crude membranes prepared from xHas1 (DG42)-transfected COS-1 cells.
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DISCUSSION |
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Gene families typically arise through a process of sequential gene duplication and divergence. In addition to relatedness based upon simple sequence conservation, family members may share other characteristics such as location within the genome, similarity of flanking genes (for gene families that have arisen by large genome-wide duplications (44)), and the locations of exon-intron boundaries within the genes (45, 46). We have previously reported the identification of a mammalian gene family encoding putative hyaluronan synthases. The human and mouse HAS genes are located on three separate autosomes within the mammalian genome (24). This suggests that the HAS gene family arose comparatively early in vertebrate evolution consistent with the existence of the HAS gene family in X. laevis (Fig. 1). Furthermore, sequence alignments indicated that an apparent HAS2 orthologue exists in the zebrafish (Fig. 1). In addition to HAS1 (DG42), HAS2, and HAS3 orthologues, a unique HAS-related sequence, designated xHAS-rs, was identified in Xenopus. cDNA clones predicted a protein of 583 amino acids that was similar in structure to other HAS members and most closely related to the xHas1 (DG42) protein (65% identity).
The conserved genomic structures of vertebrate HAS genes, including xhas1 (DG42) and xHAS-rs, suggest that they represent a single gene family arising from a common ancestral gene. All HAS genes share a common exon-intron boundary, between exons 2 and 3. Based upon shared exon-intron boundaries, the HAS genes could be split into two subfamilies (Fig. 4 and Table I). Our data support a model of three sequential gene duplication events; the first event generating two related genes that diverged to form the HAS1 and HAS2 lineages, followed by two additional events to generate HAS1 and HAS-rs and HAS2 and HAS3, respectively. Our future experiments will attempt to trace the origin of the vertebrate HAS gene family.
Northern analyses demonstrated that the three mammalian HAS genes have distinct patterns of expression in the developing embryo and in the adult, suggesting that the regulatory elements that control transcription of these genes have diverged substantially. However, the embryonic expression patterns of mouse Has genes were very similar to those of their orthologues in the developing Xenopus embryo (Fig. 5A). This suggests that although the transcriptional regulatory elements of HAS genes have diverged substantially between genes, the regulatory elements may have been essentially conserved between species. Significantly, the embryonic pattern of expression of mouse Has1 was the most restricted and corresponded closely to the pattern observed for Xenopus Has1 (DG42). Thus, our genomic structure and expression data strongly suggest that mouse Has1 represents the orthologue of Xenopus DG42. Thus, we propose a re-evaluation of the nomenclature for the X. laevis DG42 gene and its encoded product and suggest that this gene be named xhas1.
The functions of the mammalian HAS proteins and Xenopus Has1 (DG42) have been previously assessed by ourselves and other investigators (13-18, 26-29). These studies have employed in vitro transcription/translation, expression in bakers' yeast, and expression in a number of established mammalian cell lines. We have extended these studies to a functional comparison of vertebrate HAS enzymes in a single mammalian cell line, COS-1. Results from our studies suggest that vertebrate HAS enzymes are not functionally equivalent. Thus, mouse Has1, although previously shown to be active in other mammalian cell lines (13, 15), was not significantly active in COS-1 cells. In contrast, mouse Has2 and mouse Has3 expression led to the formation of substantial HA-dependent pericellular coats. However, the size of the HA synthesized in vitro by Has2 membranes was substantially larger than that synthesized by Has3 membranes. Interestingly, membrane preparations of Xenopus Has1 (DG42) expressing COS-1 cells possessed substantial HA synthase activity in vitro and synthesized a comparatively small hyaluronidase-sensitive polymer, yet COS-1 and 293 cells failed to form HA-dependent pericellular coats in culture. Thus, it appears that polymer size and subsequent fate of the newly synthesized HA may be regulated by expression of a specific HAS enzyme in a given cell type.
The most recently identified HAS family member, Xenopus
HAS-rs, has been inactive in all functional assays performed to date. Genomic structure and expression analyses support the hypothesis that
the xHAS-rs gene duplicated from the xhas1
(DG42) gene. All of our efforts to identify a mammalian
orthologue have failed. Significantly, expressed sequence tag (EST)
clones for all three mammalian HAS genes have been identified through
homology searches of public domain data
bases.3 No other HAS-related
sequences have been identified. It is possible, therefore, that the
xHAS-rs gene arose by a duplication event that occurred
after the divergence of the amphibian lineage. Alternatively, this gene
may have arisen before the amphibian divergence and subsequently been
lost from some vertebrate lineages. It is entirely possible that the
open reading frame for the xHAS-rs gene is not stably
expressed and that this gene is thus non-functional. The sequence
around the predicted translation initiation codon (ATG) of
xHAS-rs does not conform to the most favorable Kozak
initiation signal of A or G at 3 base pairs.
The vertebrate HAS enzymes are related to other eukaryotic
-glycosaminyltransferases, including the chitin and cellulose synthases, at the primary amino acid sequence level. These gene families may have evolved from independent origins, their sequence identities being the result of functional convergence. There are many
examples of enzymes that catalyze the same reaction evolving independently. These include the superoxide dismutases, alcohol dehydrogenases, and serine proteases (reviewed in Ref. 47). Alternatively, it is possible that the eukaryotic chitin, cellulose, and HA synthases have evolved through divergent evolution from a common
ancestral eukaryotic
-glycosaminyltransferase and thus constitute a
super family of genes.
The S. pyogenes hyaluronan synthase, HasA, is encoded within
the HAS operon, which encodes three polypeptides including HasA, HasB
(a UDP-glucose dehydrogenase), and HasC (a UDP-glucose
pyrophosphorylase) (48). Similar operons occur in other Gram-positive
bacteria; for instance the operon controlling type 3 polysaccharide
capsule biosynthesis in Streptococcus pneumoniae.
Significantly, the Cap3B glycosyltransferase enzyme encoded within this
operon is also flanked by ORFs encoding a UDP-glucose dehydrogenase and
a UDP-glucose pyrophosphorylase (49). Furthermore, Cap3B is 26%
identical to HasA and creates a similar polysaccharide, consisting of
1
3-linked disaccharide units of cellobiuronic acid
(GlcUA
1
4Glc) (50). It is likely, therefore, that the HAS operon
of group A streptococci evolved in the context of other prokaryotic
capsule polysaccharide synthase operons, rather than by horizontal gene
transfer (51) from eukaryotes as has been recently proposed (52). This
would suggest that HAS enzymes have evolved independently on at least two occasions, to generate the prokaryotic and eukaryotic enzymes, respectively. As genes encoding additional related
-glycosaminyltransferases are cloned, the evolution of these enzymes
can be more fully investigated. In particular, the cloning of
invertebrate (Drosophila or crab for instance) or vertebrate
(Paralipophrys trigloides, the blennie, a teleost fish, one
of the rare vertebrates that appears to synthesize chitin within its
pectoral fins (53)) chitin synthase genes would represent a major
advance in this area.
In conclusion, we have attempted to define genetic, transcriptional, and functional relationships among vertebrate HA synthases. Differences in mRNA expression patterns in concert with apparent functional differences suggest that there are multiple levels of regulation of HA biosynthesis in vertebrates. Future experiments will continue investigation into the molecular evolution of this gene family and will consider the respective role and functional relationships of HA synthases in vivo using the mouse as a model.
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ACKNOWLEDGEMENTS |
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We thank Jeffrey S. Olson, April E. Mengos, and Tammy Brehm-Gibson for outstanding technical assistance; the Molecular Biology Core Facility at Mayo Clinic Scottsdale for oligonucleotide synthesis and automated sequencing; the Protein Core Facility at Mayo Clinic Rochester for peptide synthesis; Drs. Naoki Itano and Koji Kimata at the Institute for Molecular Science of Medicine, Aichi Medical University, Japan, for the kind gift of the mouse Has1 cDNA; Dr. Douglas DeSimone at University of Virginia, Charlottesville, for the generous gift of staged X. laevis embryonic RNAs and adult tissues; "Marvelous" Marv Ruona and Julie Jensen for graphical expertise; Dr. James J. Lee for helpful discussion; and all members of the McDonald laboratory, Mayo Clinic Scottsdale, for continued support and encouragement.
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FOOTNOTES |
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* This work was supported by individual National Research Service Award 1 F32 HL09311-01 (to A. P. S.), by American Heart Association, Arizona Affiliate, Beginning Grant-in-aid Fellowship AZGB-19-96 (to A. P. S.), and by funds from the Mayo Foundation for Education and Research.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.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF015780 (X. laevis HAS-related sequence, xHAS-rs cDNA), AF015779 (X. laevis xHas2 partial cDNA), AF015778 (xHas3 partial cDNA), AF015776 (chicken, G. gallus, chas2 partial cDNA), and AF015777 (chicken chas3 partial cDNA).
Present address and to whom correspondence should be addressed:
Rowe Program in Genetics, Dept. of Biological Chemistry, School of
Medicine, Tupper Hall (MS1A), University of California, Davis, CA
95616. Tel.: 530-752-0389; Fax: 530-752-3516; E-mail:
apspicer{at}ucdavis.edu.
1 The abbreviations used are: HA, hyaluronan; HAS, hyaluronan synthase; PCR, polymerase chain reaction; ORF, open reading frame; kb, kilobase; UTR, untranslated region; RACE, rapid amplification of cDNA ends; TRU, turbidity reducing unit.
2 P. DeAngelis, personal communication.
3 A. P. Spicer and J. A. McDonald, unpublished observations.
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REFERENCES |
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