*Unité de Génétique Moléculaire Animale-UR 1061 (INRA/Université de Limoges), Institut des Sciences de la Vie et de la Santé, Faculté des Sciences, Limoges, France;
UPRES1074, Glycobiologie et Biotechnologie, Faculté des Sciences, Limoges, France;
Centre National de la Recherche Scientifique, Laboratoire de Chimie Biologique, Villeneuve d'Ascq, France;
and
§Glycobiologie INSERM U 504/Université Paris Sud XI, Villejuif, France
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Abstract |
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Introduction |
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Core-fucosylated N-glycans are widely observed in many mammalian glycoproteins and are especially abundant in brain tissue (Shimizu et al. 1993
). They are also present in insect cells, in which fucose can be either
1
6 or
1
3 linked, although difucosylated glycans have also been found in these cells (Staudacher and Marz 1998
). In plants, core fucosylation is always performed by an
3-fucosyltransferase (Fichette-Lainé et al. 1997).
As with the tumor marker -f
toprotein, the level of human
6-fucosylated oligosaccharides is very low in serum glycoproteins, but it increases dramatically in malignant diseases (Miyoshi et al. 1997
; Noda et al. 1998
). Recently, it was reported that core fucosylation affected the antenna flexibility of N-linked biantennary oligosaccharides and also prevented the action of glycoasparaginase (Noronski and Mononen 1997
). Such changes could modify further processing of oligosaccharides by specific glycosyltransferases (Stubbs et al. 1996
; Noronski and Mononen 1997
). Moreover, core fucose would be implicated in the early steps of development, particularly in normal migration of stem cells, as it is required by the
2
8 sialyltransferase for the polysialylation of the neural cell adhesion molecule (Kojima et al. 1996
).
The first 6-fucosyltransferase was characterized using a partially purified enzyme extract (Longmore and Schachter 1982
). An active secreted form of this enzyme was identified in platelets after blood clotting (Kaminska, Glick, and Koscielak 1998
). Recently, the enzyme was purified from porcine brain (Uozumi et al. 1996
) and a human gastric cancer cell line (Yanagidani et al. 1997
). The partial sequencing of these proteins allowed two highly conserved cDNAs (D89289 and D86723, respectively).
All known fucosyltransferases are type II transmembrane proteins with four distinct domains: cytoplasmic, transmembrane, hypervariable, and catalytic. The catalytic domain resides in the luminal compartment of trans-Golgi vesicles (Paulson and Colley 1989
) and appears to be globular. This hypothesis has been recently reinforced by the determination of the three-dimensional crystal structure of the bovine ß4-galactosyltransferase, whose catalytic domain is a single conical structure with a large pocket at the base (Gastinel, Cambillau, and Bourne 1999
).
Although fucosyltransferases have not yet been crystallized, experiments have been carried out to understand the molecular basis of fucosylation. This has allowed the identification of amino acids involved in different steps of the catalytic process and in acceptor and donor specificities. Truncation experiments on human 3/4-fucosyltransferases have identified the location of the catalytic domain and several amino acids in the hypervariable stem domain that specify the acceptor substrate (Xu, Loc, and Macher 1996
). More precisely, it appeared that amino acids at the two ends of the catalytic domain affected substrate specificity and affinity (Vo et al. 1998
; Nguyen et al. 1998
). Other sequence analyses have illustrated that different conserved peptide motifs specify each fucosyltransferase family and revealed that
2- and
6-fucosyltransferases have common peptide conserved motifs (Breton, Oriol, and Imberty 1998
; Oriol et al. 1999
). Recently, we demonstrated that a single amino acid in the hypervariable stem domain of vertebrate
3/4-fucosyltransferases determines the type-1 or type-2 transfer specificity (Dupuy et al. 1999
). Additionally, it was shown that a few amino acids of the hypervariable domain flanking the transmembrane domain contain signals for sublocalization and stabilization into the Golgi apparatus (Grabenhorst and Conradt 1999
).
The predicted genomic structure of the FUT8-coding sequences differs from that of all other known mammalian fucosyltransferases, which have monoexonic coding sequences (Costache et al. 1997a
; Yamaguchi et al. 1999
). Until now, none of these genomic organizations has been determined. In the present paper, we report the intron/exon organization of the coding sequence of the bovine
6-fucosyltransferase gene and compare it to human and other vertebrate, invertebrate, bacterial, and plant enzymes.
FUT8 reveals a fascinating segmentation in several exons, corresponding to successive functional peptide domains suggesting a possible three-dimensional core-structure. In addition to gene organization, several conserved motifs in different species (mammals, invertebrates, and bacteria) reveal how an ancestral fucosyltransferase gene (Costache et al. 1997a
; Oriol et al. 1999
) has evolved and led to the emergence of the
2- and the
6-fucosyltransferase gene families, which are structurally and functionally divergent.
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Materials and Methods |
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Rapid Amplification of 5' and 3' cDNA Ends (RACE)
The Marathon cDNA amplification kit (CLONTECH) was used to produce a library of adapter-ligated double-stranded cDNA from bovine brain, heart, kidney, lung, and spleen tissues. The first strand synthesis was carried out at 42°C for 1 h with the 52mer CDS primer, 100 U of the MMLV reverse transcriptase in a total volume of 10 µl, and 1 µg of poly(A)+ mRNA from each tissue as a template. The second-strand synthesis was performed at 16°C for 90 min in a total volume of 80 µl, containing the enzyme mixture (RNase H, E. coli DNA polymerase I, and DNA ligase), the second-strand buffer, the dNTP mixture, and the first-strand reaction product. cDNA ends were then made blunt by adding to the reaction 10 U of T4 DNA polymerase and incubated at 16°C for 45 min. Double-stranded cDNA was phenol/chloroform extracted, ethanol precipitated, and then resuspended in 10 µl of water. Half of this volume was used for ligation of CLONTECH adapter to cDNA ends. The ligation reaction was carried out for 16 h at 16°C in a total volume of 10 µl, using 1 U of T4 DNA ligase. The resulting cDNA library was diluted to a final concentration of 0.2 µg/ml.
The 5' end of FUT8b cDNA was PCR-amplified using 5 µl of the library as template with primers AP1 and P3 (table 1 ). The 50-µl reaction mixture contained 5 nmol of each dNTP, 20 pmol of each primer, 50 nmol MgCl2, and 2.5 U Advantage Taq DNA polymerase (CLONTECH). After a pre-PCR cycle (1 min at 94°C, 15 s at 65°C, and 2 min at 68°C), 35 cycles were performed (10 s at 94°C, 15 s at 65°C, and 50 s at 68°C), followed by a last extension step at 68°C for 5 min. The resulting PCR product was diluted (1/100) and reamplified under the same conditions using nested oligonucleotides AP2 and P4 (table 1 ). The same procedure was followed to identify the 3' end, with the two specific primers P6 and P5 combined with AP1 and AP2, respectively. Final PCR products were cloned and sequenced.
DNA Sequencing
Sequencing was performed using T7 promoter and pUCM13rev primers for DNA cloned into pGEM-T Easy vector, or directly with primers for PCR amplification of long PCR products. A dye labeling chemistry (kit PRISM Ready Reaction Ampli Taq FS) and the ABI Prism 310 Genetic Analyzer (Perkin Elmer, Norwalk, Colo.) were used.
Northern Blot Analysis
Two micrograms of brain, heart, kidney, lung, and spleen mRNAs, obtained from CLONTECH, were denatured and fractionated with 0.8% formaldehyde agarose gel electrophoresis and then blotted onto nylon Hybond-N+ membranes. After prehybridization for 4 h at 42°C in a buffer containing 50% (v/v) deionized formamide, 1% (w/v) SDS, 1 x Denhardt's, 5.5 x SSC, 21.5 mM Na2HPO4, 11% (w/v) dextran sulfate, and 7 µg/ml salmon sperm DNA, the membrane was hybridized overnight at 42°C, with probe I. A bovine ß-actin probe was used as positive control. Membranes were washed three times at 42°C with 2 x SSC/0.1% SDS, 1 x SSC/0.1% SDS, and 0.2 x SSC/0.1% SDS, respectively, for 15 min each and analyzed with a PhosphorImager 445 SI (Molecular Dynamics) and autoradiographed.
Transient Expression of Bovine cDNA
The full-length FUT8b cDNA (2,921 bp) was amplified using forward (COS/1: 5'-GGGGATCCGCGGAGACCGCCTCTG-3') and reverse (COS/2: 5'-TGTCTAGAAAACATTGAGTACTAAAGAATC-3') primers. The PCR product was double-digested by BamHI and XbaI and inserted into the pcDNAI/Amp (pcDNAI/Amp/FUT8b) in order to transiently transfect COS-7 cells. SuperFect transfection reagent (QIAGEN) was used according to the protocol described by the manufacturer. After 48 h, COS-7 cells were harvested and washed with PBS, and proteins were subsequently extracted in lysis buffer (1% [v/v] Triton X100, 10 mM sodium cacodylate [pH 6], 20% [v/v] glycerol, 1 mM DTT) for 2 h at 4°C. The suspension was then centrifuged at 12,000 x g for 10 min at 4°C, and the supernatant was used for assays.
For expression into E. coli (strain AD494 (DE3) pLysS), two primers, Ec1 and Ec2 (table 1 ), including BamHI and NheI restriction sites, respectively, were used to amplify cDNA. The PCR product was then double-digested by the two corresponding restriction enzymes and subsequently introduced into pET-25b(+), a prokaryotic periplasmic expression vector. Transformed bacteria were grown in LB medium supplemented with ampicillin (100 µg/ml) at 37°C for 4 h. Induction of truncated FUT8b expression was performed by adding IPTG (1 mM). Bacteria were pelleted and then resuspended in extraction buffer containing Tris (30 mM, pH 7.9), sucrose 20% (w/v), and EDTA (0.1 mM). After incubation for 10 min at room temperature under slow agitation, the suspension was centrifuged for 10 min at 12,000 x g. Then, MgSO4 (5 mM) was added to the pellet, and the periplasmic fraction used for assays was extracted, after a 5 min incubation at 4°C under shaking, by a new centrifugation of 10 min at 12,000 x g.
6-Fucosyltransferase Enzyme Assays
Assays were made as previously described by Yazawa et al. (1998)
, at 37°C for 4 h in an incubation mixture containing 322 pmol (222,580 cpm) GDP-[14C]fucose, 4 µmol HEPES-NaOH buffer (pH 7.0), 10 nmol acceptor substrate Man3GlcNAc4, and 50 µg of protein in a total volume of 50 µl. Final products were then applied on a PEI-cellulose thin layer chromatography plate (Merck, Darmstadt, Germany) and developed with phosphate buffer (1 mM, pH 8.0). Radioactivity of
6-fucosylated acceptor was estimated by phosphorimaging.
Sequence Analysis
LALIGN (Huang and Miller 1991
) was used for mammalian FUT8 cDNA comparisons. Peptide sequence homologies were analyzed by BLASTP (Altschul et al. 1990
) in the SwissProt data bank. An exhaustive FASTA search of DNA and protein databases (Pearson and Lipman 1988
) was performed with human FUT1 (M35531), human FUT2 (U17894), human Sec1 (U17895), Caenorhabditis elegans
2-fucosyltransferase (Z92830_5), Helicobacter pylori
2-fucosyltransferase (AF076779), Arabidopsis thaliana
2-fucosyltransferase (AF154111_1), human FUT8 (D89289), and Azorhizobium caulinodans nodZ (L18897_8). These searches gave 87
2-fucosyltransferases and 9
6-fucosyltransferases. Putative fucosyltransferase open reading frames (ORFs) were identified in large genomic sequences (human AL109847, containing 186,110 bp, and Drosophila melanogaster AC018043, containing 34,322 bp) with the FGENE program from the Sanger Center genomic analysis Web tools.
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Results |
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Southern and Northern Blot Analysis
In order to determine how many homologous sequences exist, a monoexonic probe (probe I) was used to sample bovine, human, and porcine genomes. For each digestion, only one band was detected, suggesting that there is only one 6-fucosyltransferase gene in bovine, human, and porcine genomes (fig. 2A
).
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Exonic Structure of the Coding Sequence
To investigate the genomic structure of the FUT8b coding sequence, we generated a probe containing the entire ORF (1,728 bp) or a part of the fifth exon (probe I; see Materials and Methods). Southern blots probed with the entire ORF revealed more than one band (data not shown). Under the same stringency conditions, only one band was depicted with probe I (fig. 2A
) irrespective of the restriction enzymes used. Subsequent long-distance PCR analysis made with primers designed against ORF revealed variation in amplified fragment size depending on the template used.
Using genomic DNA, PCR products always appeared considerably longer than those obtained using cDNA. Altogether, these results suggested that the FUT8b ORF is interrupted by introns. A long PCR approach in the 5' and 3' directions was retained based on starting primers S1 and S2 (table 1 ). A genomic PCR product of about 5 kb (fig. 3 ), compared with the cDNA counterpart (329 bp), proves that the coding sequence was interrupted by intronic segments. In order to determine the exon/intron organization of the coding sequence, we used successive primers, allowing us to walk along the ORF (S3, S4, S5, S6, S7, S1inv, S2inv, S3inv, S6inv; table 1 ). Sequence analysis of the amplified products allowed us to identify five exons and four introns spanning 40 kb (fig. 4A and B ).
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Discussion |
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The genomic organization of the FUT8b coding sequence consists of five exons and four introns (fig. 4A and B
), spanning 40 kb. Exon 1 (375 bp from ATG) corresponds to the cytoplasmic and transmembrane domains and presents in its 3' end a luminal part including a region homologous to cytoskeleton proteins, with up to 61% similarity on 57 aa (table 3
). Exon 2 (707 bp) encodes the stem domain whose 3' end shows a proline-rich region including a XPXPPYXP sequence (residues 298305) similar to the SH3-binding motif XPXXPPPFXP (in bovines, Y replaces F), usually composed of 10 aa (Pawson 1995
). The following three exons (exon 3, 177 bp; exon 4, 181 bp; exon 5, 288 bp to TAA) contain the catalytic domain. The peptide sequence encoded by exon 5 exhibits a significant homology (up to 52% on 60 aa) with the SH3 domain (table 3
). As recently shown for the postsynaptic density-95 protein (McGee and Bredt 1999
), this SH3 domain could have intramolecular interactions with the proline-rich region. The resulting loop might constitute a tulip-shaped scaffolding, including the catalytic domain corresponding to exons 3 and 4. A similar folded structure has previously been proposed for the crystal structure of the bovine ß4-galactosyltransferase T1 (Gastinel, Cambillau, and Bourne 1999
). This is comparable with bovine exon 3, which encodes a peptide sequence homologous to DNA gyrases (60% on 33 aa). This enzyme binds nucleotides via a specific binding domain crucial for its activity (Cullis, Maxwell, and Weiner 1997
). The peptide sequence encoded by exon 4 presents 57% homology on 27 aa with the glucosamine fructose-6-phosphate aminotransferase (table 3
). The luminal part of FUT8, encoded by exon 1, might be involved in protein-protein interactions with certain Golgi proteins analogous to cytoskeleton proteins (table 3
). These interactions could stabilize the correct orientation of the catalytic loop. The three-dimensional protein structure might also depend on disulfide bridges between the well-conserved cysteines (fig. 1
). Recently, we and others have shown that interactions between amino acids at both ends of the catalytic domain play a crucial role in the core structure of the fucosyltransferases (Holmes et al. 2000).
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Sequence comparisons of the 87 2-fucosyltransferases and the 9
6-fucosyltransferases available in GenBank/EBI, including the new bovine sequence, confirmed the existence of the three highly conserved peptide motifs in both enzyme families. The first two motifs have already been reported to have a common conserved amino acid structure in both the
2- and the
6-fucosyltransferase families, whereas the third motif (motif III) appeared to be more specific to each group of enzymes (Oriol et al. 1999
). However, the present analysis on a larger series of sequences with less stringent conditions suggests the existence of two conserved hydrophobic positions in motif III, which, in addition to the highly conserved distance between motifs II and III, also suggest a common origin for motif III (table 4
).
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In the organisms depicted in figure 6
, the 6-fucosyltransferase genes have evolved independently, as revealed by their structural differences. Nevertheless, in mammals, the enzymes act on the same donor and acceptor substrates, suggesting that the well-conserved peptide motifs I, II, and III (table 4
) might be involved in catalysis. Interestingly, these motifs are homologous to those found in
2-fucosyltransferases, with the spacing between them being remarkably maintained within the two enzyme families. This organization suggests a common origin and an emergence by duplication of an ancestor gene. However, between
2- and
6-fucosyltransferase genes, some amino acids differ in each motif, suggesting separate evolution and divergence after the duplication event.
The exon/intron structure of 6-fucosyltransferase genes is similar to the genomic organization of the mung bean
3-fucosyltransferase gene, in which the ORF comprises four exons (Leiter et al. 1999
). In both cases, enzymes transfer fucose on the asparagine-linked GlcNAc, in
1
6 linkage for mammals and in
1
3 linkage for plants. Both gene families have been considered ancestral (Oriol et al. 1999
). If we accept that
2- and
6-fucosyltransferases originated from a single duplication event of a common ancestor, they must have different evolutionary rates, since 20%30% differences are observed among the different vertebrate
2-fucosyltransferases, whereas only 2%5% differences are observed among the vertebrate
6-fucosyltransferases.
Our findings are in agreement with the exon theory of gene formation (Gilbert 1987
), which argues that the first proteins were mainly aggregates of short polypeptides and that subsequent genes were initially assembled from small exons. The bovine FUT8b gene is a new and good example of a direct correlation between exons and protein unit domains, as was previously shown for hemoglobin (Go 1981
) and other proteins. It could result from a shuffling of different coding exons, with the introns helping by recombination mechanisms to assemble the first genes (Gilbert, De Souza, and Long 1997
). An intron loss by retrotransposition (Gilbert, De Souza, and Long 1997
; Wierinckx et al. 1999
; Capy 2000
) could have occurred and led to the emergence of the other fucosyltransferases characterized by their monoexonic coding sequences (Oulmouden et al. 1997
; Wierinckx et al. 1999
; Barreaud et al. 2000
). Such a mechanism has already been observed for the human phosphoglycerate kinase gene, for which an autosomal intronless copy exists (McCarrey et al. 1987
), but also for the Drosophila alcohol dehydrogenase gene, a messenger which was retrotransposed and became a part of a newly originated functional gene (Long and Langley 1993
; Long, Wang, and Zhang 1999
). Interestingly, it was reported that in the yeast Saccharomyces cerevisiae, the paucity of introns could be attributed to ancestral retrotransposition mechanisms, based on homolog recombination (Fink 1987
).
In invertebrates (C. elegans and D. melanogaster), the three conserved peptide motifs (motifs I, II, and III) are in three separate exons in the 2-fucosyltransferase genes (data not shown), whereas in
6-fucosyltransferase genes, they reside in the same exon (fig. 6
). In the mammalian (bovine and human)
6-fucosyltransferase genes, the three motifs are on distinct exons. This could signify that some introns have appeared more recently during evolution, or that the gene organization of the invertebrate motifs has been conserved from the common
2/6-fucosyltransferase ancestor.
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Acknowledgements |
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Footnotes |
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1 Abbreviations: FUT8, human gene encoding the 6-fucosyltransferase; FUT8b, bovine gene encoding the
6-fucosyltransferase; ORF, open reading frame.
2 Keywords: fucosyltransferase
exon/intron organization
conserved motifs
3 Address for correspondence and reprints: Raymond Julien, Institut des Sciences de la Vie et de la Santé, Faculté des Sciences, Université de Limoges, 123, avenue Albert Thomas, 87060 Limoges cedex, France. E-mail: rjulien{at}unilim.fr
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