Identification and Characterization of Galectin-9, a Novel beta -Galactoside-binding Mammalian Lectin*

(Received for publication, October 31, 1996, and in revised form, December 9, 1996)

Jun Wada and Yashpal S. Kanwar Dagger

From the Department of Pathology, Northwestern University Medical School, Chicago, Illinois 60611

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
FOOTNOTES
Acknowledgments
REFERENCES


ABSTRACT

A 36-kDa beta -galactoside mammalian lectin protein, designated as galectin-9, was isolated from mouse embryonic kidney by using a degenerate primer polymerase chain reaction and cloning strategy. Its deduced amino acid sequence had the characteristic conserved sequence motif of galectins. Endogenous galectin-9, extracted from liver and thymus, as well as recombinant galectin-9 exhibited specific binding activity for the lactosyl group. It had two distinct N- and C-terminal carbohydrate-binding domains connected by a link peptide, with no homology to any other protein. Galectin-9 had an alternate splicing isoform, exclusively expressed in the small intestine with a 31-amino acid insertion between the N-terminal domain and link peptide. Sequence homology analysis revealed that the C-terminal carbohydrate-binding domain of mouse galectin-9 had extensive similarity to that of monomeric rat galectin-5. The presence of galectin-5 in the mouse could not be demonstrated by polymerase chain reaction or by Northern or Southern blot genomic DNA analyses. Sequence comparison of rat galectin-5 and rat galectin-9 cDNA did not reveal identical nucleotide sequences in the overlapping C-terminal carbohydrate-binding domain, indicating that galectin-9 is not an alternative splicing isoform of galectin-5. However, galectin-9 had a sequence identical with that of its intestinal isoform in the overlapping regions in both species. Southern blot genomic DNA analyses, using the galectin-9 specific probe derived from the N-terminal carbohydrate-binding domain, indicated the presence of a novel gene encoding galectin-9 in both mice and rats. In contrast to galectin-5, which is mainly expressed in erythrocytes, galectin-9 was found to be widely distributed, i.e. in liver, small intestine, thymus > kidney, spleen, lung, cardiac and skeletal muscle > reticulocyte, brain. Collectively, these data indicate that galectin-9 is a new member of the galectin gene family and has a unique intestinal isoform.


INTRODUCTION

There is growing evidence that specific carbohydrate moieties and their putative binding proteins, i.e. lectins, play diverse roles in mammalian physiology and development and in various pathological states (1). The mammalian lectins are classified into four categories, C-type lectins (including selectins), P-type lectins, pentraxins, and galectins; the latter are referred to as S-type or S-Lac lectins (2, 3). Galectins are endowed with two essential biochemical properties: 1) characteristic amino acid homologous sequences; and 2) affinity for beta -galactoside sugars, i.e. carbohydrate-binding domain. In addition, all the known galectins lack a signal peptide, have a cytoplasmic localization, and are secreted as soluble proteins by a nonclassical secretory pathway (4). Seven mammalian galectins, i.e. galectins-1 (5), -2 (6), -3 (7), -4 (8), -5 (9), -7 (10, 11), and -8 (12), have been cloned and characterized. Structural analyses of various galectins indicate the presence of homodimers of carbohydrate-binding domains in galectin-1 and galectin-2, a monomer of the carbohydrate-binding domain in galectin-5, and a single polypeptide chain with two carbohydrate-binding domains joined by a link peptide in galectin-4 and galectin-8. Galectin-3 has a carbohydrate-binding domain, a short N-terminal segment, consisting of PGAYPG(X)1-4 repeats, and an intervening stretch of amino acids, enriched with proline, glycine, and tyrosine (2, 3). Although the overall structure of galectins varies, each carbohydrate-binding domain is highly conserved and is encoded by three major exons (13, 14). Expression analyses have revealed that certain galectins display a restricted distribution, e.g. galectin-2 in hepatoma, galectin-4 in the small intestine, galectin-5 in erythrocytes, and galectin-7 in keratinocytes. Galectins with a broad tissue distribution include galectin-1, expressed in cardiac, smooth, and skeletal muscles, neurons, thymus, kidney, and placenta; galectin-3, present in blood cells, intestine, kidney, and neurons; and galectin-8, expressed in liver, kidney, cardiac muscle, lung, and brain (2, 3, 5 -12). Some of these are believed to be involved in cell:cell or cell-matrix interactions (2).

Such interactions between cell adhesion molecules and extracellular matrix glycoproteins, i.e. collagen, laminin, fibronectin, and proteoglycans, and their receptors (integrins) are highly relevant during embryonic development, including organogenesis of the kidney (15, 16). Conceivably, these interactions also involve the participation of other matrix- and plasmalemmal-bound macromolecules, such as galectins-1, -3, and -8, that are abundantly expressed in the developing metanephric kidney. In view of these considerations, studies were initiated to search for other developmentally regulated novel galectins that may be pertinent to the biology of cell-cell and cell-matrix interactions. In this communication, we report the identification and characterization of a new galectin, i.e. galectin-9, including its isoform and relationship with galectin-5.


EXPERIMENTAL PROCEDURES

Degenerate Oligonucleotide-based Polymerase Chain Reaction (PCR)1 and Cloning and Nucleotide Sequencing of PCR Products Isolated from Mouse Embryonic Kidney

Total RNA was extracted from embryonic metanephroi of CD-1 mice at day 13 and day 17 of gestation by the guanidinium isothiocyanate-CsCl centrifugation method (17), and poly(A)+ RNA was isolated by utilizing a FastTrack 2.0 kit (Invitrogen). First strand cDNA was synthesized by using Moloney murine leukemia virus-reverse transcriptase (RT, Rnase H-) and oligo(dT)25d(G/C/A) as a primer (CLONTECH) (18, 19). Double-stranded cDNA was prepared by using a mixture of Escherichia coli DNA polymerase I, RNase H, and E. coli DNA ligase (20, 21). Subsequently, an adaptor-ligated double-stranded cDNA was generated by a Marathon cDNA Amplification Kit (CLONTECH), which was used as template DNA for rapid amplification of 5'-cDNA ends (RACE) (19, 22) by PCR (23, 24). A degenerate antisense 18-mer oligonucleotide primer, corresponding to the beta -galactoside-binding conserved sequence HFNPRF, was designed with the following nucleotide sequence: 5'-(GA)AA(GATC)C(GT)(GATC)GG(GA)TT(GA)AA(GA)TG-3'. 5'-RACE PCR was performed using template DNA in a 50-µl reaction mixture, containing 5 µl of 10× buffer (500 mM Tris-HCl (pH 9.2), 160 mM (NH4)2SO4, 17.5 mM MgCl2), 200 µM concentrations of each dNTP, 0.2 µM adaptor primer 1 (supplied in the kit), 1 µM degenerate antisense primer, and 1 µl of polymerase mix; the latter is a mixture of 14.3 µl of Taq/Pwo (Boehringer Mannheim) and 5.7 µl of TaqStart antibody (CLONTECH). The reaction was carried out for 35 thermal cycles, each consisting of 1.5 min at 95 °C, 2 min at 37 °C, 3 min at 68 °C, and a final 10-min extension at 68 °C. PCR products purified by agarose gel electrophoresis, and subcloned into pCRTMII vector (Invitrogen). Plasmid DNAs from ~100 colonies were prepared, and the vector inserts were sequenced by the dideoxy chain termination method using modified T7 DNA polymerase (Sequenase, Amersham). A sequence homology search was performed using the Network BLAST program.

cDNA Library Screening, Isolation of Full-Length Galectin-9 cDNA and Nucleotide Sequencing

A lambda ZAP mouse newborn kidney cDNA library was prepared and screened as detailed previously (25, 26). Briefly, about 0.5 × 106 phage recombinants were plated, and nitrocellulose filter lifts of phage plaques were prepared. The filters were hybridized with a [alpha -32P]dCTP-random-radiolabeled 226-base pair (bp) mouse galectin-9 cDNA fragment obtained by the degenerate PCR cloning method described above. Positive plaques were isolated and purified by dilutional secondary and tertiary screening. Phage cDNAs were amplified, agarose gel purified, and ligated into pBluescript phagemid KS(+), using XL1-Blue MRF' E. coli (Stratagene). Single-stranded DNAs were prepared by VCSM13 helper phage and sequenced. Hydropathic (27), sequence homology (28), and protein structural analyses (29) were performed using GCG PACKAGE 8.0.1.

Expression Analysis of Galectins by Reverse Transcriptase (RT)-Polymerase Chain Reaction in Various Tissues and Nucleotide Sequencing

Total RNAs from various organs of adult mice and rats were used for the synthesis of cDNAs (26). For the synthesis of cDNA from fetal red blood cells, 13-day-old mouse embryos were bled into the culture medium. Pellets of fetal erythrocytes were prepared by centrifugation and utilized for isolation of mRNA by the Micro-Fast Track mRNA isolation kit (Invitrogen). In addition, total RNAs from spleen and reticulocytes of phenylhydrazine-induced anemic mice and rats (30) were isolated to prepare the cDNA. PCR analyses were performed on cDNAs of various organs by utilizing primers with the following nucleotide sequences: for mouse, 5'-GCATTGGTTCCCCTGAGA TAG-3' (MG9SE) and 5'-CGTTCCAGAGACCGGATCC-3' (MG9AS); and for rat, 5'-GCGTT GGTTCTCCCAAGACAG-3' (RG5SE) and 5'-CCTAGGCCAGAGACCTTC-3' (RG5AS) (Fig. 3A). To further ensure the detection of expression of galectin(s) in mouse reticulocytes, RACE PCR was also performed using adaptor-ligated double-stranded cDNA and primer set adaptor primer 1 and MG9AS. The PCR products were gel purified, ligated into pCRTMII cloning vector (Invitrogen), and sequenced as described above.


Fig. 3. RT-PCR and sequences analyses of galectin-5 and galectin-9. A, schematic alignment comparison of mouse galectin-9 and rat galectin-5 cDNAs. Translated regions of both the galectins are boxed. Rat galectin-5 lacks the link peptide, and it has a single carbohydrate-binding domain. MG9SE, MG9AS, RG5SE, and RG5AS are designations and locations of the mouse galectin-9 and rat galectin-5 primers used for PCR analyses. B, RT-PCR of mouse galectin-9 and rat galectin-5. cDNAs from various adult and embryonic tissues were amplified by mouse primers MG9SE and MG9SE. PCR products of ~1.0 kbp (Kb) (galectin-9) are seen in various tissues (panel a). In addition, a long isoform (~1.1 kbp) is seen expressed only in the small intestine (panel a). PCR products (~0.5 kbp) of the putative mouse homologue of galectin-5 are not amplified from cDNA of any organ tissue (panel a). In panel b, rat cDNAs from various organs were amplified by primers RG5S.E. and RGAS. Rat galectin-5 (~0.5 kbp), rat galectin-9 (~1.0 kbp), and rat galectin-9 intestinal isoform (~1.1 kbp) cDNAs are amplified. These PCR products were sequenced. d, day; MW, molecular weight. C, sequence alignment of rat galectin-9 (rg9) and rat galectin-5 (rg5) cDNA reveals ~93.6% homology in the overlapping regions. The observation that these sequences are not identical in the overlapping segment supports the notion that galectin-9 is not an alternative splicing isoform of galectin-5.
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Expression of Galectins by Northern Blot Analyses

Analyses were performed on total RNA, isolated from various adult mouse and rat tissues, as described previously (26). In brief, 30 µg of total RNA of each organ were glyoxalated, subjected to 1% agarose gel electrophoresis, and transferred to a nylon membrane (Pall Biosupport). Under high stringency conditions, the membranes were hybridized with a [alpha -32P]dCTP-random-radiolabeled "mouse galectin-9 cDNA probe," generated by PCR using MG9S.E. and MG9AS primers (see above, and see Figs. 3A and 4C). In addition, separate membrane filters were hybridized with a radiolabeled "mouse galectin-9-specific cDNA probe," generated by PCR using sense (5'-TACTGGACCAATCCAAGGAGG-3') and antisense (5'-AGTAGAGAACATCTGTCCAG-3') primers (Figs. 3A and 4C). The latter cDNA probe specifically detects the expression of galectin-9 since it spans only the N-terminal carbohydrate-binding domain, which is absent in galectin-5; whereas the mouse galectin-9 cDNA probe spans the N- as well as C-terminal carbohydrate-binding domains and detects the presence of both galectin-9 and galectin-5 since they share 80.9% nucleotide sequence homology in the C-terminal carbohydrate-binding domain. beta -Actin (GenBankTM accession no. M62174[GenBank], ATCC) cDNA was used as a control.


Fig. 4. Expression of galectin-9 and galectin-5 by Northern blot analyses in mouse (A) and rat (B) tissues. A, in mouse tissues, ~2-kbp transcripts of galectin-9 are observed in Northern blots of various tissues hybridized with G9 cDNA probe. The degree of expression is as follows: liver, small intestine, thymus > kidney, spleen, lung, cardiac and skeletal muscle > reticulocyte, brain. Smaller transcripts, corresponding to size of galectin-5, are not observed in any tissue. B, in rat tissues, in hybridization with G9 cDNA probe (top), transcripts of galectin-9 (~2 kbp) and of galectin-5 (~1.5 kbp) are detected. Galectin-5 is seen expressed in reticulocyte and spleen. In hybridization with G9-specific cDNA probe, single ~2-kbp transcripts, corresponding to the size of galectin-9, are observed in various rat tissues (middle). The shorter transcripts, corresponding to the size of galectin-5, are not observed in blots hybridized with G9-specific cDNA probe (middle). The tissue distribution of galectin-9 in the rat is similar to that of the mouse; however, its expression is relatively low in the thymus and substantially lower in kidney and skeletal muscle. The beta -actin concentrations are similar in various mouse and rat tissues. C, schematic drawing depicting the locations of galectin-9 (G9) and G9-specific cDNA probes in mouse galectin-9 gene.
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Southern Blot Analyses of Genomic DNA

To confirm the presence or absence of galectin-9 and -5 in mouse and rat species, genomic Southern blot analyses were performed as described previously (31). Genomic DNAs from rat and mouse livers were isolated. Aliquots (20 µg each) of genomic DNAs were digested with EcoRI, XbaI, PstI, BamHI, and HindIII restriction enzymes; subjected to agarose gel electrophoresis; and transferred to nylon membranes. The transferred DNAs were hybridized either with the [alpha -32P]-radiolabeled mouse galectin-9 probe (G9 probe), or the galectin-9-specific cDNA probe (G9-specific probe) under high stringency conditions.

Fusion Protein Expression and Purification

Expression of recombinant protein with C-terminal c-myc-(His)6 tag for mouse galectin-9 was carried out with pTrcHis2 vector (Invitrogen). As controls, mouse galectin-1 and -3 cDNAs, containing entire coding segments, were generated by RT-PCR using mouse newborn kidney cDNA. Primers were: 5'-for galectin-1, GCTTCAATCATGGCCTGT-3' and 5'-GGCTGGCTTCACTCAAAGGC-3' (32); and for galectin-3, 5'-GCACAGAGAGCATACCCAGG-3' and 5'-CTTCTGGCTTAGATC ATG-3' (33). PCR products of galectins-1 and -3 were subcloned into pCRTMII vector and sequenced. cDNA inserts of these 3 mouse galectins were reamplified by using the following primer sets: 5'-GGGGGG<UNL>GGATCC</UNL>CATGGCCTGTGGTCTGGTC-3' and 5'-GGG GGG<UNL>AAGCTT</UNL>CTCAAAGGCCACGCACTT-3' for galectin-1; 5'-GGGGGG<UNL>GGATCC</UNL>AATGGC AGACAGCTTTTCG-3' and 5'-GGGGGG<UNL>AAGCTT</UNL>GATCATGGCGTGGTTAGC-3' for galectin-3; 5'-GGGGGG<UNL>GGATCC</UNL>GATGGCTCTCTTCAGTGCC-3' and 5'-GGGGGG<UNL>AAGCTT</UNL>TGTCTG CACGTGGGTCAG-3' for galectin-9. BamHI and HindIII restriction sites were also introduced, and they are underlined in each of the primer sequences. The generated PCR products were digested with BamHI and HindIII, gel purified, and ligated into pTrcHis2A plasmid to prepare galectins-1 (pTrcHis2/G1), -3 (pTrcHis2/G3), and -9 (pTrcHis2/G9) constructs. The constructs were transfected into the TOP10 bacterial host (Invitrogen) and sequenced to ensure proper in-frame ligation and Taq polymerase fidelity. The bacteria were allowed to grow in 1 liter of LB media until an A600 of 0.6 was achieved. Expression of fusion proteins was induced by the addition of 1 mM isopropyl-1-thio-beta -D-galactopyranoside and further cultured for 5 h. To isolate recombinant proteins, bacterial pellets were prepared, and suspended in 100 ml of either MEPBS buffer (9, 12) or Tris-dithiothreitol (DTT) buffer (34) containing 1.25% Triton X-100, 10 mM benzamidine, 10 mM epsilon -amino-n-caproic acid, and 2 mM phenylmethanesulfonyl fluoride. They were lysed by sonication, and the lysate was centrifuged at 20,000 × g at 4 °C for 30 min. Supernatants were applied to a 10-ml lactosyl-Sepharose column (Sigma), unbound proteins were washed, and fusion proteins were eluted with either MEPBS buffer or Tris-DTT buffer containing 200 mM lactose. The elution buffers containing beta -mercaptoethanol or DTT were always freshly prepared to prevent oxidation of galectins by air (34, 35). Fractions of 1 ml were collected, and the protein concentration was determined by the Bradford method, using a Bio-Rad protein assay kit (Bio-Rad Laboratories). Purified recombinant proteins were suspended in a sample buffer (4% SDS, 150 mM Tris-HCl (pH 6.8), 20% glycerol, 0.1% bromphenol blue, 1% beta -mercaptoethanol) and subjected to 12.5% SDS-polyacrylamide gel electrophoresis (PAGE) (36). Gel bands were visualized after staining with Coomassie Blue.

Immunoprecipitation

To determine the molecular size of endogenous mammalian galectin-9, immunoprecipitation experiments were performed. Polyclonal antibody was raised by immunizing rabbits with a synthetic peptide, KTQNFRPAHQAPMAQT. Its sequence stretches between 148 and 162 amino acid residues of the link peptide of mouse galectin-9 (Fig. 1B). An additional lysine residue at the N-terminal was used for conjugation of the peptide to keyhole limpet hemocyanin. For immunoprecipitation experiments, newborn mouse liver and thymus were radiolabeled in vivo by an intraperitoneal injection of [35S]methionine (0.05 mCi/g body weight). After 24 h, the organs were harvested, homogenized in Tris-DTT buffer containing 10 mM benzamidine, 2 mM phenylmethanesulfonyl fluoride, 1% Triton X-100, 10 mM benzamidine, and 10 mM epsilon -amino-n-caproic acid and sonicated. The homogenates were centrifuged at 10,000 × g for 30 min at 4 °C, and the supernatants were applied to lactosyl-Sepharose columns and eluted with 0.2 M lactose in Tris-DTT buffer. Immunoprecipitation was performed by adding 10 µl of anti-mouse galectin-9 antibody to 0.5 ml of eluate, containing ~0.5 × 10-6 dpm. The eluate-antibody mixture was gently swirled in an orbital shaker for 18 h. Protein A-Sepharose 4B (Pharmacia) was added to the antibody-galectin-9 complex and mixed for 2 h, following which the pellets were prepared and washed four times with Tris-DTT buffer. The immunoprecipitated complexes were dissolved in a sample buffer and subjected to 12.5% SDS-PAGE under reducing conditions. The gels were fixed in 10% acetic acid, treated with 1 M salicylic acid, and dried, and autoradiograms were prepared. Preimmune serum was used as a control.


Fig. 1. Deduced amino acid (aa)sequence and structural analyses of mouse galectin-9. A, schematic drawing of mouse galectin-9 and its intestinal isoform. Two carbohydrate-binding domains are connected by a link peptide. The intestinal isoform insertion is located between the N-terminal domain and the link peptide. B, deduced amino acid sequence of mouse galectin-9 and its isoform. The intestinal isoform insertion sequence is boxed. The amino acid sequence of the synthetic peptide used for antibody production is double-underlined. C, hydrophobicity analyses shows that galectin-9 lacks signal peptide and hydrophobic transmembrane segment.
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Enzyme-linked Immunosorbent Assays (ELISA)

To assess the specificity of the anti-galectin-9 antibody, ELISA assays were performed (37, 38). Wells of RIA/EIA titer plates (Costar) were coated with 50 µl of synthetic peptide solution (100 µg/ml) in 20 mM NaHCO3, pH 9.0. The plates were allowed to dry overnight at 37 °C. 100 µl of ice-cold methanol were added to each well the next day and allowed to evaporate for 2 h at 37 °C. To reduce nonspecific binding of the antibody, 200 µl of bovine serum albumin solution (5 mg/ml), prepared in phosphate-buffered saline (PBS), was added, and plates were left at 22 °C for 1 h. The wells were washed twice with PBS, and 0.5 mg of antibody (IgG fraction) in 50 µl of bovine serum albumin-PBS (100 µg/ml) solution was added to the first well. Log dilutions of the antibody were made in successive wells, and incubation was carried out with gentle shaking for 90 min. Wells were rewashed three times with PBS containing 0.05% Tween 20. Then horseradish peroxidase-conjugated goat anti-rabbit IgG (Cappel) diluted 1:1000 in bovine serum albumin-PBS solution was added, and incubation was extended for 60 min. After another three washes with Tween 20, 100 µl of a solution containing 9 parts 3,3',5,5'-tetramethylbenzidine and 1 part H2O2 (Bio-Rad Laboratories) was added. For color development, the plates were left in the dark for 30 min. The colorimetric reaction was stopped by the addition of 100 µl of 0.3 M H2SO4. Finally, readings at A490 were made and plotted against log dilutions of the antibody.

For competitive inhibition ELISA assay, 250 µg of recombinant galectin-9 were added in the first well of the peptide-coated titer plate as a competitive antigen along with 0.5 µg of the antibody in 50 µl of the PBS-bovine serum albumin solution. Log dilutions of the antigen were made in successive wells, while the antibody concentration was kept constant. Conditions for incubation with secondary antibody and colorimetric reactions were the same as described above. Readings at A490 were made and plotted against the log dilutions of the antigen.


RESULTS

Identification of Novel beta -Galactoside-binding Lectin in the Embryonic Kidney

Using degenerate oligonucleotide-based PCR cloning, PCR products of ~250 bp in both the 13-day and 17-day embryonic kidney were identified. The products were ligated into pCRTMII vector, and ~100 clones were isolated and sequenced. By homology search (National Center for Biotechnology Information), 73 clones were identified as mouse galectin-1, while 28 clones had other unrelated cDNA sequences. Translation of one additional clone with 226 bp indicated that it had a consensus sequence of the galectin gene family. However, it did not show >50% overall sequence homology to other known galectins. Using the 226-bp clone as a hybridization probe, preliminary Northern blot analyses of embryonic and neonatal mouse kidney tissues revealed a ~2.0-kilobase pair (kbp) transcript. We then proceeded to screen the newborn kidney lambda ZAP cDNA library, using 226-bp clone as a hybridization probe. A 1418-bp clone (GenBankTM accession no. U55060[GenBank]) was isolated and was designated as "galectin-9."

Structural Analyses of Novel Mouse 36-kDa Galectin-9

The 1418-bp clone had an open reading frame (35-1000) and a potential initiation codon. The open reading frame encoded 322 amino acids with a predicted size of ~36-kDa protein. Alignment sequence analyses of this protein with known galectin family members revealed that it had 2 homologous (38.5%) N-terminal (147 amino acids) and 1 C-terminal (149 amino acids) carbohydrate-binding domain, connected by a 26-amino acid link peptide (Figs. 1A, 1B, and 2). Both domains contained galectin sequence motifs, which are conserved in all the known galectins (Fig. 2). Among the known mammalian galectins, only galectin-4 and galectin-8 have two carbohydrate-binding domains joined by a link peptide (Table I). The link peptide of galectin-9 (mG9) had no homology with those of the galectin-4 and -8 (Fig. 2, 148-173 amino acids). Hydropathic analysis revealed that like other galectins, it lacks a classical signal sequence and a transmembrane hydrophobic segment (Fig. 1C). By secondary structural analyses, both domains shared characteristics similar with those of several beta  sheets, a common structural feature of galectins.


Fig. 2. Comparison of carbohydrate-binding domains of galectins. Amino acid sequences of human (h) galectin-1 (5), human galectin-2 (6), human galectin-3 (7), rat (r) galectin-3 (8), rat galectin-5 (9), human galectin-7 (10), and rat galectin-8 [12) are aligned by Pileup program (GCG sequence analysis package). Gx, galectin-x; m, mouse. Residues with shared identity are boxed.
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Table I.

Percentage of sequence similarity of mouse galectin-9 with other galectins at the nucleotide and amino acid levels

Sequences are compared with human galectin-1 (J04456[GenBank]), human galectin-2 (M87842[GenBank]), human galectin-3 (J02921[GenBank]), rat galectin-4 (M73553[GenBank]), rat galectin-5 (L36862[GenBank]), human galectin-7 (L07769[GenBank]), and rat galectin-8 (U09824[GenBank]). Overlapped regions of nucleotide similarity are variable and thus are adjusted by the Gap program (GCG Wisconsin package) to obtain highest homology scores.
Galectins Nucleotide level Amino acid level
CTa domain 1-147 Link peptide 147-173 CT domain 174-322

hGalectin-1 45.5 26.5 30.2
hGalectin-2 44.6 23.4 27.1
hGalectin-3 46.9 40.9 41.4
rGalectin-4 51.5 NT 48.2 41.5
Link 15.3
CT 35.6 43.7
rGalectin-5 80.9 41.7 81.3
hGalectin-7 49.7 32.5 41.3
rGalectin-8 49.6 NT 37.4 38.4
Link 7.6
CT 34.9 44.0
mGalectin-9 NT 38.5
CT 38.5

a  NT, N-terminal; CT, C-terminal; h, human; r, rat; m, mouse.

Galectin-9 Is a Novel Member of the Galectin Family

At the amino acid level, the C-terminal domain of galectin-9 shared an extensive homology (81.3%) with rat erythrocyte galectin-5 (9). Also at the nucleotide level, its 5'-untranslated segment, the 3' half of the coding region and the 3'-untranslated regions had a 80.3% homology with rat galectin-5 (Table I, Fig. 3A). To ensure that the cloned galectin-9 is not an isoform of galectin-5, a PCR cloning strategy was used. Primers were designed from 5'- and 3'-untranslated regions of galectin-9 cDNA (Fig. 3A, MG9SE and MG9AS). RT-PCR analyses of various mouse tissue mRNAs (heart, brain, liver, kidney, spleen, muscle, and thymus) yielded ~1.0-kbp products (Fig. 3B, panel a). In addition, a ~1.1-kbp product, exclusively expressed in the small intestine, was observed (Fig. 3B, panel a). By sequence analysis, the ~1.1-kbp product revealed a 31-amino acid insertion between the N-terminal domain and the link peptide (GenBankTM accession no. U55061[GenBank]) and was designated as a mouse galectin-9 intestinal isoform. Except for the 31-amino acid insertion, the intestinal isoform had a 100% homology with mouse galectin-9. Since rat galectin-5 was originally isolated from reticulocytes, RT-PCR was also carried out on mouse cDNAs, prepared from phenylhydrazine-induced reticulocytes and embryonic erythrocytes. Only ~1.0-kbp products were detected, and the expected 0.5-kbp product, i.e. mouse homologue of rat galectin-5, could not be amplified. RACE PCR was also performed using 47-bp adaptor-ligated mouse reticulocyte cDNA, and it also yielded only one ~1.1-kbp product; the 0.5-kbp band of galectin-5 was not detected.

Since RT-PCR and 5'-RACE PCR failed to document the presence of galectin-5 in mouse, we then selected the primer set RG5SE and RG5AS from rat galectin-5 cDNA (GenBankTM accession no. L36862[GenBank]), which corresponds to mouse MG9SE and MG9AS by a sequence alignment program (Fig. 3A). With these rat primers, RT-PCRs were performed on cDNAs from various adult rat tissues, including reticulocytes. Two bands, i.e. ~1.0 and ~0.5 kDa, were observed in several tissues, and another ~1.1-kbp band was confined to the small intestine only (Fig. 3B, panel b). Analysis of the ~0.5-kbp product revealed that it had a nucleotide sequence identical with that of rat galectin-5 (30-472 bp, GenBankTM accession no. L36862[GenBank]), while the ~1.0-kbp product (GenBankTM accession no. U59462[GenBank]) had a 88.9% homology to mouse galectin-9. Thus, the ~1.0-kbp product was regarded as the rat homologue of mouse galectin-9. Sequence analysis of the ~1.1-kbp product (GenBankTM accession no. U72741[GenBank]) showed that it is an isoform of rat galectin-9 since it had a 32-amino acid insertion between the N-terminal carbohydrate domain and the link peptide, as in the mouse galectin-9 intestinal isoform. These two rat PCR products, the 0.5- and 1.0-kbp rat galectins-5 and -9 shared a 93.6% homology in the 443-bp overlapping region of C-terminal carbohydrate-binding domain (Fig. 3C), while the rat galectin-9 and its intestinal isoform had a 100% identity in the 974-bp overlapping region, spanning the N- and C-terminal carbohydrate-binding domains. These results indicate that the newly cloned galectin-9 is not an alternate splicing isoform of galectin-5, that it has a long intestinal isoform in both rats and mice, and that galectin-5 is not present in the mouse.

Expression of Galectins by Northern and Southern Blot Analyses

Using the galectin-9 (G9) cDNA probe (Fig. 4C), a ~2-kbp single transcript was observed in various mouse tissues (Fig. 4A). Smaller mRNA transcripts, corresponding to putative mouse galectin-5, were not detected. mRNA expression of galectin-9 in various mouse organs was as follows: liver, small intestine, thymus > kidney, spleen, lung, skeletal muscle, heart > reticulocyte, brain (Fig. 4A, upper panel). In rat tissues, the G9 cDNA probe hybridized with transcripts of ~2 and ~~1.5 kbp, corresponding to galectin-9 and galectin-5, respectively (Fig. 4B, upper panel). The 1.5-kbp mRNA transcripts of rat galectin-5 were abundantly expressed in reticulocytes and spleen. Although, mRNA expression of galectin-9 (~2 kbp) in various rat tissues was similar to that in the mouse, its expression was relatively low in the thymus and substantially lower in kidney and skeletal muscle (Fig. 4B, upper panel). By using the G9-specific probe, only ~2-kbp transcripts were observed, and smaller transcripts (~1.5 kbp) were not detected in various rat tissues (Fig. 4B, middle panel).

Southern blot analyses, using the G9 cDNA probe, revealed a single major band in various restriction enzyme digests of mouse genomic DNA (Fig. 5A, left panel). Identical results were obtained for mouse genomic DNA digests in blots hybridized with the G9-specific cDNA probe (Fig. 5A, right panel), supporting the presence of a gene encoding galectin-9 only. Rat genomic DNA digests revealed multiple bands when the G9-specific cDNA probe was used for Southern blot hybridization analyses (Fig. 5A, right panel); while hybridization with the G9 cDNA probe revealed a few additional bands in various restriction enzyme digests (Fig. 5B, left panel), suggesting the presence of galectin-9 and -5 genes in rat genomic DNA.


Fig. 5. Genomic Southern blot analyses of galectin-9 and galectin-5 in mouse (A) and rat (B). A, in the mouse, a single band is visualized in the Southern blot of various restriction enzyme digests of genomic DNA hybridized with the G9 cDNA probe (left). Identical bands are observed in blots hybridized with the G9-specific cDNA probe (right), indicating the presence of the gene encoding galectin-9 only. B, in the rat, multiple bands are visualized in the Southern blot of restriction enzyme digests of DNA hybridized with the G9-specific cDNA probe (right). Additional bands are observed in Southern blots hybridized with the G9 probe (left), indicating the presence of the genes encoding galectin-9 and galectin-5 in the rat.
[View Larger Version of this Image (41K GIF file)]


Recombinant Galectin-9 Exhibits Lactose-binding Activity

Preliminary experiments revealed a time-dependent increasing isopropyl-1-thio-beta -D-galactopyranoside-inducible expression of recombinant galectins, which was maximal at 5 h in total E. coli lysates, prepared in the presence of DTT or beta -mercaptoethanol. SDS-PAGE of the eluates of bacterial lysates from lactosyl-Sepharose column revealed ~39-kDa, ~37-kDa, and ~17-kDa bands of rat galectins-9, -3, and -1, respectively (Fig. 6A, lanes 3-8).


Fig. 6. SDS-PAGE of c-myc-(His)6-tagged fusion proteins of mouse galectin-1, -3, and -9 in E. coli (A) and immunoprecipitation profile of galectin-9 (B). A, SDS-PAGE analyses of E. coli lysate and fusion proteins prepared in the presence of beta -mercaptoethanol in phosphate-buffered saline (MEPBS) (lanes 1, 3, 5, and 7) or DTT in Tris-HCl buffer (Tris-DTT) (lanes 2, 4, 6, and 8). Fusion proteins of galectin-9 (~39 kDa; lanes 3 and 4), galectin-1 (~17 kDa; lanes 5 and 6) and galectin-3 (~37 kDa; lanes 7 and 8) are visualized after Coomassie Blue staining. The molecular weights of the fusion proteins also include ~3-kDa myc-(His)6 tag. B, homogenates of [35S]methionine-labeled thymus and liver were subjected to lactosyl-Sepharose chromatography, followed by immunoprecipitation of the eluates with anti-galectin-9 antibody and SDS-PAGE. A major ~36-kDa band is seen in both the liver and thymus in the SDS-PAGE autoradiogram. No band is seen in the homogenates treated with preimmune serum. Arrow, point of application of the sample.
[View Larger Version of this Image (45K GIF file)]


Immunoprecipitation and ELISA Assays

Homogenates of [35S]methionine-labeled liver and thymus were applied to a lactosyl-Sepharose column, followed by immunoprecipitation of the eluted fractions with anti-galectin-9 antibody. SDS-PAGE autoradiograms of the immunoprecipitates revealed a ~36-kDa band, indicating that endogenous galectin-9 also has lactose-binding activity and a comparable molecular weight (Fig. 6B, lanes 1 and 2). No discernible bands were observed when immunoprecipitation was performed with preimmune serum (Fig. 6B, lanes 3 and 4). Specificity of the antibody was also assessed by ELISA assay in which a fixed amount of antigen, i.e. synthetic peptide, and serial log dilutions of the antibody were used. With increasing dilutions of the antibody, a proportional decrease in A490 readings was observed (Fig. 7A). To confirm the specificity of the antibody, a competitive inhibition ELISA assay was performed. A fixed amount of diluted antibody (1:000) along with serial log dilutions of the competitive antigen, i.e. recombinant galectin-9, were added into the wells of the titer plate coated with the synthetic peptide. With increasing dilutions of the competitive antigen, a proportional increase in A490 readings was observed (Fig. 7B), documenting the specificity of anti-galectin-9 antibody.


Fig. 7. ELISA (A) and competitive inhibition-ELISA (B) profiles of galectin-9 antibody and recombinant galectin-9. A, a decrease in A490 readings is observed with increasing log dilutions of anti-galectin-9 antibody. B, an increase in A490 readings is observed with increasing log dilutions of the competitive antigen, i.e. recombinant galectin-9.
[View Larger Version of this Image (14K GIF file)]



DISCUSSION

In the present study, we have described a novel galectin, galectin-9, isolated from the embryonic kidney cDNA, using the degenerate oligonucleotide-based RACE-PCR cloning strategy. Although previous studies used traditional lactosyl-Sepharose column protein purification to identify galectins, the successful isolation of galectin-9 indicates that degenerate oligonucleotide-based RACE-PCR strategy is yet another useful method by which one can search for new galectins in various tissues. The biochemical characteristics of galectin-9 fulfill the criteria for its inclusion as a new member of the galectin family (2, 3). They include the following: 1) its deduced amino acid sequence which indicates two domains consisting of characteristic conserved sequence motifs that are implicated in binding to specific saccharides; and 2) the recombinant fusion protein (recombinant galectin-9) exhibits specific binding affinity for lactosyl groups. In addition, an endogenous protein, with an expected size of ~36 kDa, binds to lactosyl-Sepharose columns and can be immunoprecipitated by specific antibody, directed against a unique sequence of galectin-9 link peptide.

A feature common to galectin-9 and other galectins is that it lacks a classical signal sequence and a transmembrane hydrophobic segment. Thus, like other galectins that have a cytosolic distribution and are secreted as a soluble proteins by a nonclassical secretory mechanism (4), galectin-9 could be externalized with the aid of a carrier protein. Such a mechanism has been shown for other cytoplasmic proteins lacking a signal peptide, such as thymosin, interleukin-1, and fibroblast growth factor (39, 40).

Structural analyses of galectin-9 revealed some additional unique features. It consists of two distinct carbohydrate-binding domains connected by a link peptide. Among the known galectin family members, only galectin-4 (8), galectin-8 (12), and the Caenorhabditis elegans homologue (41) have similar dimeric structures. Other galectins, including galectin-1 (5) and galectin-2 (6), contain only one carbohydrate-binding domain but can function as homodimers to facilitate aggregation or agglutination of cell surface-bound glycoconjugates via noncovalent associations (3). Although galectins with two carbohydrate-binding domains may have similar agglutinating and aggregating potential, their properties could be influenced by the size and amino acid sequence of the link peptide affecting overall molecular conformation. Moreover, since the amino acid sequences of link peptides differ from one another, it raises the possibility that these may modify biological activities of various dimeric galectins in a given tissue. One of the unique features of galectin-9 is its alternate splicing isoform exclusively expressed in the small intestine. This isoform has a 31- and 32-amino acid insertion in mouse and rat, respectively. Since this insertion has no homology with the carbohydrate-binding domain sequences, it can be regarded as an extension of the link peptide. Such a long link peptide, with a stretch of 57-58 amino acids, may influence the macromolecular conformation of galectin-9 which may be necessary for certain yet to be defined functions related to the biology of intestinal epithelium. Such an extended version of the link peptide or the isoforms have not been reported in other dimeric galectins.

Analysis of the C-terminal domain of mouse galectin-9 revealed substantial sequence homology (81.3%) with rat galectin-5, while the N-terminal had a 23-48% amino acid sequence homology with other galectins. At the nucleotide level, the coding region of the C-terminal domain and the 5'- and 3'-untranslated regions had a 80.9% similarity to rat galectin-5 cDNA. Galectin-5 is a monomeric form of rat galectin, which is mainly expressed in the erythrocytes (9). Its genetic relationship with galectin-9 is not clear; i.e. are they alternate splicing isoforms, or are they derived from separate genes? Initially, we speculated that galectin-9 might be a novel isoform of galectin-5 because of its segmental sequence homology. Therefore, attempts were made to isolate putative mouse galectin-5 from various tissues by PCR cloning methods, using the primers derived from sequences of flanking the 5'- and 3'-untranslated regions of mouse galectin-9. The ~0.5 kbp PCR product, corresponding in size to galectin-5, could not be amplified in mouse cDNA, instead, we identified galectin-9 and an intestinal alternate splicing isoform of galectin-9. In contrast, in cDNAs of various rat tissues, three PCR products, corresponding to galectin-5, galectin-9, and the intestinal isoform of galectin-9, were amplified when primer sequences derived from the 5'- and 3'-untranslated regions of the reported rat galectin-5 cDNA were used. However, a comparison of the cDNA sequences of rat galectin-5 with those of galectin-9 did not show identical nucleotide sequences in the overlapping regions; thus, galectin-9 is not an alternate splicing form of galectin-5. The existence of a long intestinal isoform in rat as well as in the mouse, with nucleotide sequences identical with that of galectin-9 in the respective species, further supports the notion that galectin-9 is indeed a novel member of the galectin gene family.

To further characterize the relationship between the galectin-5 and galectin-9, Northern blot and genomic Southern blot analyses were performed. By Northern blot analyses, galectin-9 mRNA transcripts were found in various tissues with a wide distribution in both rats and mice. However, galectin-5 mRNA transcripts were detected largely in rat reticulocytes and spleen. Galectin-5 mRNA transcripts were absent in mouse reticulocytes as well as in other mouse tissues. By using the galectin-9 (G9)-specific cDNA probe, genomic Southern blot analyses affirmed the existence of a unique gene encoding galectin-9 protein both in rat and mouse. In mouse genomic Southern blot analyses, a single band was detected in various restriction enzyme digests of the genomic DNA after hybridization with G9 specific or G9 cDNA probes; thus, the existence of the galectin-5 gene in the mouse is doubtful. Certainly, in our hands, attempts to elucidate the presence of mouse galectin-5 by RT-PCR, prime] RACE PCR, Northern blot, or Southern blot genomic DNA analyses were unsuccessful.

By a recent homology search through the GenBankTM, we have also found that Homo sapiens RCC313 mRNA (Z49107[GenBank]) (42)2 has a 70% homology with mouse galectin-9 and thus regard it as the human homologue of galectin-9. This cDNA was isolated by immunoscreening of a human Hodgkin's lymphoma lambda ZAP library with autologous patient serum and was found to be distributed in lymphoid tissues (42). Since, in both mice and rats, galectin-9 is expressed in lymphoid tissues, such as in the thymus and spleen, its potential role in the biology of the immune system would be anticipated, although this galectin is originally isolated from embryonic kidney. In addition, a 17.5-kDa galectin with a high amino acid sequence similarity to galectin-5 has been reported in the rat kidney (43). This galectin may be galectin-5 or a proteolytic fragment of galectin-9.

In summary, although the C-terminal carbohydrate domain of galectin-9 shares extensive homology with galectin-5, there are distinct differences between the two, such as different tissue distributions and carbohydrate-binding domains. Finally, like certain other galectins (2), galectin-9 seems to be developmentally regulated in various embryonic tissues,3 including the kidney, the organogenesis of which is heavily influenced by cell-cell and cell-matrix interactions (15, 16). Since galectins are believed to be involved in cell-matrix interactions (44-49) and are developmentally regulated, it would be of a great interest to investigate their relevance in various embryological processes regulating cell growth and differentiation (32, 50).


FOOTNOTES

*   Supported by National Institutes of Health Grant DK28492. 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) U55060[GenBank] (mouse galectin-9), U55061[GenBank] (mouse galectin-9 intestinal isoform), U59462[GenBank] (rat galectin-9), and U72741[GenBank] (rat galectin-9 intestinal isoform).


Dagger    To whom requests for reprints and correspondence should be addressed: Dept. of Pathology, Northwestern University Medical School, 303 E. Chicago Ave., Chicago, IL 60611. Tel.: 312-503-0084; Fax: 312-503-0627.
1    The abbreviations used are: PCR, polymerase chain reaction; RACE, rapid amplification of 5'-cDNA ends; bp, base pair(s); kbp, kilobase pair(s); RT, reverse transcriptase; G9, galectin-9; MEPBS buffer, phosphate-buffered saline with 4 mM beta -mercaptoethanol, 2 mM EDTA; DTT, dithiothreitol; Tris-dithiothreitol buffer, 20 mM Tris (pH 7.4), 5 mM EDTA, 150 mM sodium chloride, 1 mM DTT; PAGE, polyacrylamide gel electrophoresis, 2 mM phenylmethanesulfonyl fluoride, 1% Triton X-100; ELISA, enzyme-linked immunosorbent assay; PBS, phosphate-buffered saline.
2    Unpublished observations.
3    Unpublished data.

Acknowledgments

We are grateful to Dr. Samuel H. Barondes and his colleagues for valuable suggestions during the course of this investigation and for suggesting the inclusion of galectin-9 as a new member of the galectin gene family. We are also thankful to Drs. D. G. Scarpelli, E. I. Wallner, and K. Alveraz for carefully editing the manuscript.


REFERENCES

  1. Varki, A. (1993) Glycobiology 3, 97-130 [Abstract]
  2. Barondes, S. H., Castronovo, V., Cooper, D. N. W., Cummings, R. D., Dickamer, K., Feizi, T., Gitt, M. A., Hirabayashi, J., Hughes, C., Kasai, K., Leffler, H., Liu, F., Lotan, R., Mercurio, A. M., Monsigny, M., Pillai, S., Poirier, F., Raz, A., Rigby, P. W. J., Rini, J. M., and Wang, J. L. (1994) Cell 76, 597-598 [Medline] [Order article via Infotrieve]
  3. Barondes, S. H., Cooper, D. N. W., Gitt, M. A., and Leffler, H. (1994) J. Biol. Chem. 269, 20807-20810 [Free Full Text]
  4. Cooper, D. N. W., and Barondes, S. H. (1990) J. Cell Biol. 110, 1681-1691 [Abstract]
  5. Couraud, P.-O., Casentini-Borocz, D., Bringman, T. S., Griffith, J., McGrogan, M., and Nedwin, G. E. (1989) J. Biol. Chem. 264, 1310-1316 [Abstract/Free Full Text]
  6. Gitt, M. A., Massa, S. M., Leffler, H., and Barondes, S. H. (1992) J. Biol. Chem. 267, 10601-10606 [Abstract/Free Full Text]
  7. Robertson, M. W., Albrandt, K., Keller, D., and Liu, F. T. (1990) Biochemistry 29, 8093-8100 [Medline] [Order article via Infotrieve]
  8. Oda, Y., Herrmann, J., Gitt, M. A., Turck, C. W., Burlingame, A. L., Barondes, S. H., and Leffler, H. (1993) J. Biol. Chem. 268, 5929-5939 [Abstract/Free Full Text]
  9. Gitt, M. A., Wiser, M. F., Leffler, H., Herrmann, J., Xia, Y.-R., Massa, S. M., Cooper, D. N. W., Lusis, A. J., and Barondes, S. H. (1995) J. Biol. Chem. 270, 5032-5038 [Abstract/Free Full Text]
  10. Madsen, P., Rasmussen, H. H., Flint, T., Gromov, P., Kruse, T. A., Honore, B., Vorum, H., and Celis, J. E. (1995) J. Biol. Chem. 270, 5823-5829 [Abstract/Free Full Text]
  11. Magnaldo, T., Bernard, F., and Darmon, M. (1995) Dev. Biol. 168, 259-271 [CrossRef][Medline] [Order article via Infotrieve]
  12. Hadari, Y. R., Paz, K., Dekel, R., Mestrovic, T., Accili, D., and Zick, Y. (1995) J. Biol. Chem. 270, 3447-3453 [Abstract/Free Full Text]
  13. Gitt, M. A., and Barondes, S. H. (1991) Biochemistry 30, 82-89 [Medline] [Order article via Infotrieve]
  14. Rosenberg, I. M., Iyer, R., Cherayil, B., Chiodino, C., and Pillai, S. (1993) J. Biol. Chem. 268, 12393-12400 [Abstract/Free Full Text]
  15. Saxen, L (1987) Organogenesis of the Kidney., Cambridge University Press, New York
  16. Ekblom, P. (1995) in Molecular and Cellular Aspects of Basement Membranes (Rohrbach, D. H., and Timpl, R., eds), pp. 359-383, Academic Press, New York
  17. Chirgwin, J. M., Przybyla, A. E., MacDonald, R. J., and Rutter, W. J. (1979) Nucleic Acids Res. 18, 5294-5299
  18. Borson, N. D., Sato, W. L., and Drewes, L. R. (1992) PCR Methods & Applications 2, 144-148 [Medline] [Order article via Infotrieve]
  19. Chenchik, A., Moqadam, F., and Siebert, P. (1995) CLONTECHniques X 1,, 5-8
  20. Gubler, U., and Hoffman, B. J. (1983) Gene 25, 263-269 [Medline] [Order article via Infotrieve]
  21. Shelness, G. S., Kanwar, Y. S., and Blobel, G. (1988) J. Biol. Chem. 263, 17063-17070 [Abstract/Free Full Text]
  22. Siebert, P. D., Chenchik, A., Kellogg, D. E., Lukyanov, K. A., and Lukyanov, S. A. (1995) Nucleic Acids Res. 23, 1087-1088 [Medline] [Order article via Infotrieve]
  23. Barnes, W. M. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 2216-2220 [Abstract]
  24. Cheng, S., Fockler, C., Barnes, W. M., and Higuchi, R. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 5695-5699 [Abstract]
  25. Kanwar, Y. S., Liu, Z. Z., Kumar, A., Wada, J., and Carone, F. A. (1996) Kidney Int. 48, 1646-1659
  26. Wada, J., Kumar, A., Liu, Z., Ruoslahti, E., Reichardt, L., Marvaldi, J., and Kanwar, Y. S. (1996) J. Cell Biol. 132, 1161-1176 [Abstract]
  27. Kyte, J., and Doolitle, R. F. (1982) J. Mol. Biol. 157, 105-132 [Medline] [Order article via Infotrieve]
  28. Lipman, D. J., and Pearson, W. R. (1985) Science 227, 1435-1441 [Medline] [Order article via Infotrieve]
  29. Chou, P. Y., and Fasman, G. D. (1978) Adv. Enzymol. Relat. Areas Mol. Biol. 47, 45-148 [Medline] [Order article via Infotrieve]
  30. Chui, D. H. K., Patterson, M., and Bayley, S. T. (1980) Br. J. Haematol. 44, 431-439 [Medline] [Order article via Infotrieve]
  31. Liu, Z. Z., Wada, J., Alvares, K., Kumar, A., Wallner, E. I., and Kanwar, Y. S. (1993) Kidney Int. 44, 1242-1250 [Medline] [Order article via Infotrieve]
  32. Poirier, F., Timmons, P. M., Chan, C. T., Guenet, J. L., and Rigby, P. W. (1992) Development 115, 143-155 [Abstract]
  33. Cherayil, B. J., Weiner, S. J., and Pillai, S. (1989) J. Exp. Med. 170, 1959-1972 [Abstract]
  34. Frigeri, L. G., Robertson, M. W., and Liu, F.-T. (1990) J. Biol. Chem. 265, 20763-20769 [Abstract/Free Full Text]
  35. Whitney, P. L., Powell, J. T., and Sanford, G. L. (1986) Biochem. J. 238, 683-689 [Medline] [Order article via Infotrieve]
  36. Laemmli, U. K. (1970) Nature 227, 680-685 [Medline] [Order article via Infotrieve]
  37. Engvall, E., and Perlman, P. (1971) Immunochemistry 8, 871-874 [CrossRef][Medline] [Order article via Infotrieve]
  38. Keren, D. F., and Warren, J. F. (1992) Diagnostic Immunology., pp. 291-306, Williams & Wilkins, Baltimore
  39. Siders, W. M., Klimovitz, J. C., and Mizel, S. B. (1993) J. Biol. Chem. 268, 22170-22174 [Abstract/Free Full Text]
  40. Mignatti, P., and Rifkin, D. B. (1991) J. Cell. Biochem. 47, 201-207 [Medline] [Order article via Infotrieve]
  41. Hirabayashi, J., Satoh, M., and Kasai, K. (1992) J. Biol. Chem. 267, 15485-15490 [Abstract/Free Full Text]
  42. Sahin, U., Türeci, Ö., Schmitt, H., Cochlovius, B., Johannes, T., Schmits, R., Stenner, F., Luo, G., Schobert, I., and Pfreundschuh, M. (1995) Proc. Natl. Acad. Sci. U. S. A. 92, 11810-11813 [Abstract]
  43. Jung, S. K., and Fujimoto, D. (1994) J. Biochem. 116, 547-553 [Abstract]
  44. Cooper, D. N. W., Massa, S. M., and Barondes, S. H. (1991) J. Cell Biol. 115, 1437-1448 [Abstract]
  45. Sato, S., and Hughes, R. C. (1992) J. Biol. Chem. 267, 6983-6990 [Abstract/Free Full Text]
  46. Massa, S. M., Cooper, D. N. W., Leffler, H., and Barondes, S. H. (1993) Biochemistry 32, 260-267 [Medline] [Order article via Infotrieve]
  47. Zhou, Q., and Cummings, R. D. (1993) Arch. Biochem. Biophys. 300, 6-17 [CrossRef][Medline] [Order article via Infotrieve]
  48. Gu, M., Wang, W., Song, W. K., Cooper, D. N. W., and Kaufman, S. J. (1994) J. Cell Sci. 107, 175-181 [Abstract/Free Full Text]
  49. Kuwabara, I., and Liu, F. T. (1996) J. Immunol. 156, 3939-3944 [Abstract]
  50. Wells, V., and Mallucci, L. (1991) Cell 64, 91-97 [Medline] [Order article via Infotrieve]

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