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Published online before print
December 12, 2005, 10.1101/gr.3690506 Genome Res. 16:97-105, 2006 ©2006 by Cold Spring Harbor Laboratory Press; ISSN 1088-9051/06 $5.00 OPEN ACCESS ARTICLE
Letter A missense mutation in the bovine SLC35A3 gene, encoding a UDP-N-acetylglucosamine transporter, causes complex vertebral malformation1 Department of Genetics and Biotechnology, Danish Institute of Agricultural Sciences, DK-8830 Tjele, Denmark 2 Department of Animal Health, Welfare and Nutrition, Danish Institute of Agricultural Sciences, DK-8830 Tjele, Denmark 3 Department of Veterinary Pathobiology, Royal Veterinary and Agricultural University, DK-1870 Frederiksberg C, Denmark 4 Department of Radiology, Royal Veterinary and Agricultural University, DK-1870 Frederiksberg C, Denmark
The extensive use of a limited number of elite bulls in cattle breeding can lead to rapid spread of recessively inherited disorders. A recent example is the globally distributed syndrome Complex Vertebral Malformation (CVM), which is characterized by misshapen and fused vertebrae around the cervico-thoracic junction. Here, we show that CVM is caused by a mutation in the Golgi-resident nucleotide-sugar transporter encoded by SLC35A3. Thus, the disease showed complete cosegregation with the mutation in a homozygous state, and proteome patterns indicated abnormal protein glycosylation in tissues of affected animals. In addition, a yeast mutant that is deficient in the transport of UDP-N-acetylglucosamine into its Golgi lumen can be rescued by the wild-type SLC35A3 gene, but not by the mutated gene. These results provide the first demonstration of a genetic disorder associated with a defective SLC35A3 gene, and reveal a new mechanism for malformation of the vertebral column caused by abnormal nucleotide-sugar transport into the Golgi apparatus.
CVM is a recessively inherited disorder with onset during fetal development, leading to frequent abortion of fetuses or perinatal death, and vertebral anomalies (Agerholm et al. 2001
Detailed clinical characterization of CVM demonstrated a composite phenotype with axial skeletal deformities such as hemivertebrae, misshaped vertebrae, ankylosis of mainly the cervico-thoracic vertebrae, scoliosis, and symmetric arthrogryposis of the lower limb joints, craniofacial dysmorphism, as well as cardiac anomalies (Agerholm et al. 2001
The purpose of the present study was to identify the mutation responsible for CVM. The data demonstrate that the disease gene encodes a member of the solute carrier family SLC35, which are enzymes transporting nucleotide-sugars from the cytosol into the lumen of the endoplasmic reticulum and/or the Golgi apparatus (Ishida and Kawakita 2004  ). In these organelles, nucleotide-sugars are utilized by glycosyltranferases to synthesize the sugar chains of glycoproteins, glycolipids, and carbohydrate polymers. Several studies lend support for an essential role of nucleotide-sugar transportation in development and disease. Thus, in Drosophila, impaired function of Fringe connection (encoded by frc), a transporter with multisubstrate specificity, was shown to have detrimental effects on fibroblast growth factor, Hedgehog, Wingless-dependent signalling, as well as to disrupt the Notch pathway (Goto et al. 2001; Selva et al. 2001). Two Caenorhabditis elegans nucleotide-sugar transporters with mutant phenotypes have been characterized. Thus, the C. elegans sqv-7 mutant, which is defective in a homolog of frc, exhibits severe defects in vulval invagination and impairment of embryonic development, presumably reflecting an inability to transport nucleotide-sugar substrates required for glycosaminoglycan biosynthesis into the Golgi (Bulik et al. 2000; Berninsone et al. 2001; Hwang and Horvitz 2002). Furthermore, mutation of the UDP-galactose and UDP-N-acetylglucosamine transporter encoded by srf-3 in C. elegans confers resistance to bacterial infections due to failure of bacteria to adhere to the altered glycoconjugate composition of the mutant nematode cuticle (Hoflich et al. 2004). Observations on human glycosylation diseases further attest to the importance of nucleotide-sugar transportation. Thus, the human disease called congenital disorder of glycosylation (CDG) type IIc (formerly leukocyte adhesion deficiency type II) occurs when GDP-fucose uptake into the Golgi is defective, resulting in clinical manifestations such as facial dysmorphology, growth and mental retardation, and lack of cell-surface expression of fucosylated glycoconjugates like the ABH and Lewis-related blood group antigens. Also, fucose-containing carbohydrate ligands required for selectin interactions are absent, leading to leukocyte adhesion deficiency (Lubke et al. 2001; Luhn et al. 2001). Recently, a related glycosylation disorder CDG type IIf was shown to result from inactivation of the Golgi CMP-sialic acid transporter (Martinez-Duncker et al. 2005). Bovine SLC35A3 is the first nucleotide-sugar transporter shown to play a role in the development of the axial skeleton, demonstrating that some of the molecular mechanisms that operate during formation of vertebrae and ribs depend on carbohydrate modification in the Golgi apparatus. The present disease model may be exploited to predict the human clinical phenotype as well as to provide further insight into the disease mechanisms.
Genetic mapping of the disease gene Affected animals are expected to be homozygous in polymorphic markers flanking the disease locus, as all chromosomes carrying the causative mutation descended from a common founder bull (Agerholm et al. 2001 ). Therefore, we performed a genome-wide scan for regions identical-by-descent. Seven calves diagnosed with CVM based on post-mortem examination as described (Agerholm et al. 2001) plus their parents were used in the initial genome scan using a panel of 194 microsatellite markers covering all 29 autosomes with pairwise distances between 10 and 20 cM. The results revealed that all seven calves were homozygous for the same allele of marker INRA003 (59.4 cM), whereas five calves had identical alleles in an adjacent marker HUJ246 (67.9 cM) on BTA3. To confirm this observation and to more accurately define the disease locus, we expanded the analysis with additional affected calves sampled by the Danish surveillance program for genetic defects to include a total of 30 affected calves plus available parental animals, which were genotyped with an increased marker density in the interval between INRA003 and HUJ246 (Fig. 1C). The evidence for linkage was highly significant with two-point lod scores of 8.13 ( = 0.00) for BMS2790 (62.4 cM), 7.53 ( = 0.00) for INRA003 (59.4 cM), and 5.12 ( = 0.04) for ILSTS029 (64.9 cM). Haplotype analysis of the five-generation pedigree shown in Figure 1C revealed several critical recombinants that allowed us to narrow down the position of the disease gene. Thus, all affected calves were homozygous in BMS2790, and recombination between BMS2790 and the nearby markers INRA003 and ILSTS029 defined the limits of the CVM disease locus.
The cattle genome is only sparsely annotated with known genes, so in order to identify positional candidate genes we anchored the disease locus to the human genome by screening a bovine large-insert bacterial artificial chromosome (BAC) library for clones containing either one of the three markers INRA003, BMS2790, or ILSTS029. BAC end sequences were subsequently compared with the human genome sequence by BLAST searches, which showed that the INRA003-BMS2790-ILST029 interval corresponds to an
Candidate gene selection
First, we sought to verify that SLC35A3 in fact is positioned at the disease locus by building a BAC contig consisting of 22 individual clones between BMS2790 and INRA003 (Fig. 2A). Eight bovine homologs of human genes known to be located in HSA1p21.2, including SLC35A3, were successfully amplified by PCR using the BAC contig clones as templates. This result suggested that gene content and order in the CVM region and HSA1p21.2 were highly conserved between the two species.
Secondly, we examined whether supportive evidence for a causative role of SLC35A3 in CVM can be observed at the protein level. Thus, glycosylation inside the Golgi apparatus modifies a wide range of proteins, suggesting that a deficiency in Golgi nucleotide-sugar transportation should be detectable by two-dimensional protein gel analysis. Indeed, 2DE analyses of cardiac and skeletal muscle tissues revealed a series of protein spots with characteristic shifts in both molecular weight and charge consistent with changes in glycosylation (Fig. 2B). To investigate this in greater detail, we used MALDI-TOF mass spectrometry to identify the prominent protein pattern (encircled) that showed both altered migration as well as accumulation in the tissues of affected animals. All spots in the encircled patterns were identified as
Mutation detection Using shotgun sequencing of BAC DNA, we determined the complete 22,400-bp sequence of the bovine SLC35A3 gene, and established the exon-intron organization by alignment with the full-length SLC35A3 cDNA sequence. Conceptual translation of the open reading frame predicted a protein of 326 amino acids with a highly conserved sequence, showing 98% identity to the human and canine SLC35A3 transporters, and 96% and 83% sequence identity to the mouse and frog SLC35A3 transporters, respectively (Fig. 3A). To identify the putative mutation in SLC35A3, we compared the cDNA sequences of unaffected and affected calves, which uncovered a transversion (G to T) that replaces valine at position 180 with phenylalanine (Fig. 3B). No other mutations were detected. Moreover, point mutations in coding regions of several genes have been recognized to influence gene function by affecting the splicing pattern (Cartegni et al. 2002 ) We investigated this possibility by Northern blot analysis of SLC35A3 gene expression (Fig. 3C). The result revealed two large mRNA transcripts in both unaffected and CVM calves, which is consistent with the observed transcript sizes of 6.2 kb and 2.4 kb in various human tissues (Ishida et al. 1999), and there was no apparent effect of the mutation on splicing accuracy or efficiency. Subsequent large-scale genotyping strongly advocated that the V180F substitution is pathogenic. Thus, all calves diagnosed as CVM affected were homozygous with respect to phenylalanine, whereas 108 verified carriers of CVM were heterozygous. Also, we genotyped more than 1500 phenotypically normal animals descending from Carlin-M Ivanhoe Bell, and none were homozygous for phenylalanine. Furthermore, analysis of more than 500 animals of the Holstein breed selected as being unrelated to the founder and  300 animals of 12 other breeds did not identify any animals with phenylalanine at position 180. These data, taken together with the fact that valine at position 180 is evolutionarily conserved, support the conclusion that the G to T transversion in SLC35A3 is the disease-causing mutation.
Functional testing of the mutation in SLC35A3
Intense breeding programs often involve mating of descendants of a particular bull, thereby increasing the familial relationship in the cattle population. By the time it was realized that Carlin-M Ivanhoe Bell carries a lethal mutation, the widespread use of this elite bull had already increased carrier frequencies of CVM in dairy cattle to an alarming 20%-30% in many countries. This prompted a search for the disease gene, which we now have identified as the SLC35A3 gene encoding a Golgi-resident transporter of UDP-N-acetylglucosamine. Remarkably, Carlin-M Ivanhoe Bell was also a carrier of another disease called bovine leukocyte adhesion deficiency (BLAD), which is an immunodeficiency disorder caused by a recessive mutation in the gene encoding the leukocyte  2 integrin subunit CD18 (Shuster et al. 1992) on BTA1 (Rexroad et al. 1999). A decade of DNA testing has reduced the frequency of the pathogenic allele and today the disease is efficiently controlled. The two defective genes responsible for CVM and BLAD are located on different chromosomes and therefore inherited independently. Genetic testing has shown that Carlin-M Ivanhoe Bell received both disease-causing mutations from his sire Pennstate Ivanhoe Star, whereas his grandsire Osborndale Ivanhoe is a BLAD carrier, but free of CVM. This suggests that the CVM mutation was either generated in Pennstate Ivanhoe Star or that it originates from the maternal side. With the identification of the genetic basis of the CVM disease, further transmission of the mutation can now be prevented through DNA testing of animals to be used for breeding.
Haploinsufficiency for the SLC35A3 transporter appears to be tolerated because heterozygous carriers are asymptomatic, whereas in its homozygous state, the mutation typically causes death in utero. Yet some fetuses do develop to term, although with severe defects. This might suggest that the mutated transporter retains some residual activity, occasionally allowing fetal development past critical stages, or alternatively, that the lack of SLC35A3 is alleviated by partial functional compensation by another nucleotide-sugar transporter with the ability to transport UDP-N-acetylglucosamine into the Golgi lumen. Thus, SLC35D2/HFRC1, and possibly also SLC35D1 (alias UGTrel7), have transporting activity toward a range of nucleotide-sugar substrates including UDP-N-acetylglucosamine (Muraoka et al. 2001
It is as yet undefined which specific molecular and cellular functions are affected by loss of UDP-N-acetylglucosamine transportation in CVM, but the composite disease phenotype with defects in multiple tissues suggest that several pathways and biochemical mechanisms are impaired. Proteomic changes were detected in the tissues of affected calves, and biochemical characterization of these proteins will help to understand the complexity of the phenotype. For example, we identified a series of
The V180F substitution may also affect the antiporter function of SLC35A3. Thus, after uptake of nucleotide-sugars in the Golgi, the sugar moiety is transferred to various acceptors by glycosyltransferases, whereas the nucleoside diphosphate is hydrolyzed into nucleoside monophosphates by nucleoside diphosphatases. The latter reaction is crucial because nucleoside diphosphates are potent inhibitors of glycosyltransferases. Moreover, the nucleoside monophosphates are required by the nucleotide-sugar transporters, which operate as antiporters by coupling nucleotide-sugar transport into the Golgi with an equimolar export of the corresponding nucleoside monophosphate. Loss or impairment of nucleoside diphosphatases has consequences for the function of the antiport cycle and glycosylation. For example, mutants lacking the GDPase gene GDA1 in Saccharomyces cerevisiae or K. lactis showed altered glycosylation of proteins and lipids due to reduced transport of GDP-mannose (and UDP-N-acetylglucosamine in K. lactis) into Golgi vesicles as well as inhibition of glycosyltransferases (Abeijon et al. 1993
Signal transduction relying on glycosylation is likely to be affected in CVM, and an attractive model is that obstruction of the Notch pathway is a contributing factor. An argument in favor of this proposal is the phenotypic similarity between the CVM defects and diseases such as those caused by defective Notch ligands JAGGED1 in Alagille syndrome (Li et al. 1997
Mutations affecting the function of glycosaminoglycans or proteoglycans have been implicated in numerous human and mouse pathologies (Princivalle and de Agostini 2002
Genome-wide scan PCR reactions were analyzed on an ABI 377 Sequencer (Applied Biosystems) and alleles were assigned with the Genotyper program, version 2.1. Two-point linkage analysis was performed using CRIMAP 2.4 (Lander and Green 1987 ) in a pedigree comprising 85 individuals, of which 29 were affected calves. The bull KOL Nixon sired 26 of these calves and 21 shared T. Burma as the maternal grandsire. Both bulls have familial relationships with Carlin-M Ivanhoe Bell. Three different bulls also descending from Carlin-M Ivanhoe Bell sired the remaining calves.
Genomic and cDNA sequences of SLC35A3
Northern blot analysis
Proteome analysis
Protein identification
Yeast methods and flow cytometry
We are grateful to C.B. Hirschberg and C. Abeijon for providing yeast strains and the pE4 vector, and P.J. de Jong for the bovine BAC library RPCI-42. The Danish Cattle Breeding Organizations supported this work.
Article published online ahead of print. Article and publication date are at http://www.genome.org/cgi/doi/10.1101/gr.3690506. Freely available online through the Genome Research Immediate Open Access option.
5 Corresponding author. [The sequence data from this study has been submitted to GenBank under accession no. AY160683 [GenBank] . The following individuals kindly provided reagents, samples, or unpublished information as indicated in the paper: C.B. Hirschberg, C. Abeijon, and P.J. de Jong.]
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http://prowl.rockefeller.edu/profound_bin/WebProFound.exe; ProFound tool for searching protein sequence databases. http://www.phrap.org; PHRAP assembly engine.
Received January 12, 2005; accepted in revised format August 17, 2005.  CiteULike  Connotea  Del.icio.us  Digg  Reddit  Technorati What's this?
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ABSTRACT
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1-antitrypsin that was observed only in tissues from affected CVM calves. The mobility changes with a shift in pI as well as in MW indicate that aberrant protein glycosylation is associated with CVM. Moreover, the increased spot intensity of 
T mutation (indicated by an asterix) in normal (+/+), carrier (+/-), and CVM-affected (-/-) animals. (C) Northern blot analysis of SLC35A3 mRNA. Poly(A)+ RNA was isolated from kidney tissue of CVM calves and unaffected calves and analyzed by hybridizing Northern blots with a 32P-labeled SLC35A3 probe. Subsequently, the membranes were stripped and reprobed with a 32P-labeled GAPDH (glyceraldehyde-3-phosphate dehydrogenase) fragment.
