Galactosyl receptor in human testis and sperm is antigenically related to the minor C-type (Ca2+-dependent) lectin variant of human and rat liver

Galactosyl receptor, a cell surface Ca²⁺-dependent lectin with binding affinity for galactose, was evaluated by immunoblotting, immunoprecipitation, Northern blotting, and immunocytochemistry in human liver, testis, and sperm. Polyclonal antisera raised against the minor asialoglycoprotein receptor variant of rat hepatocytes (designated rat hepatic lectin-2/3, RHL-2/3), and its human liver-equivalent (designated H2), recognize native galactosyl receptor in the testis and sperm in immunoblotting, immunoprecipitation, and immunocytochemical experiments. An equivalent to the major hepatocyte asialoglycoprotein receptor variant (rat RHL-1 and human H1) was not detected. Human testis and sperm galactosyl receptor was resolved, after immunoprecipitation and immunoblotting, as a single protein component of molecular mass 50 kD. The single protein component in human testis and sperm contrasted with the doublet nature of rat testis and sperm galactosyl receptor, consisting of two components of molecular masses of 54 and 49 kD. Northern blotting experiments using radiolabeled H1 and H2 cDNA probes confirmed the presence of H2 mRNA and the lack of H1 mRNA in the human testis. Immunocytochemical studies detected specific antigenic sites on the entire surfaces of spermatogenic cells. However, immunoreactivity in epididymal and ejaculated sperm was confined to head surfaces overlying the acrosome. Results from these studies, and from previous studies in the rat, suggest that the testis/sperm galactosyl receptor is a C-type Ca²⁺-dependent lectin with possible roles in cell-cell interaction during spermatogenesis and sperm-zona pellucida binding at fertilization. © 1995 Wiley-Liss, Inc.     

Identification of rat testis galactosyl receptor using antibodies to liver asialoglycoprotein receptor: purification and localization on surfaces of spermatogenic cells and sperm

We have found that the rat testis contains a cell surface galactosyl receptor that is antigenically related to the minor species of rat liver asialoglycoprotein receptor (ASGP-r) and has binding affinity for galactose coupled to agarose. In immunoblotting experiments, rat testis galactosyl receptor (RTG-r) is recognized by antiserum raised against the minor ASGP-r species of rat liver (designated rat hepatic lectin-2/3, RHL-2/3). Antiserum raised against the major species RHL-1 does not recognize an antigenic protein equivalent to RTG-r. Triton X-100-extracted rat liver and testes preparations fractionated by affinity chromatography on galactose-agarose and resolved by SDS-PAGE under reducing conditions, show that rat liver contains both the major (RHL-1) and minor (RHL-2/3) ASGP-r species whereas rat testis displays only a receptor species comigrating with RHL-2/3. RTG-r was present throughout testicular development. The receptor was found in seminiferous tubules, cultured Sertoli and spermatogenic cells, and epididymal sperm. Indirect immunofluorescent studies show RHL-2/3-like immunoreactivity on the surface of Sertoli cell, meiotic prophase spermatocytes, spermatids, and epididymal sperm. In spermatids and sperm, the immunoreactivity is restricted to the plasma membrane overlying the dorsal portion of the head. Because of RTG-r has galactose binding affinity, is present on surfaces of Sertoli and developing meiotic and postmeiotic spermatogenic cells, and overlies a region of the intact acrosome on epididymal sperm, RTG-r may have a role in spermatogenesis and in events leading to sperm-egg recognition.     

Rat sperm galactosyl receptor: Purification and identification by polyclonal antibodies raised against multiple antigen peptides

We have previously reported the purification of rat testis galactosyl receptor, an equivalent to the Ca²⁺-dependent (C-type) minor variant of rat hepatic lectin-2/3 (RHL-2/3). We now report the purification of galactosyl receptor from rat sperm and its immunolocalization in the intact rat testis and sperm by polyclonal antibodies prepared using multiple antigen peptides (MAP) as immunogens. Two MAP antigens (designated 27-mer and 28-mer), corresponding to amino acid sequences of the carbohydrate-recognition domain (galactose) and adjacent Ca²⁺-binding sites of RHL-2/3, were used for immunization. Anti-RHL-2/3, anti-p27, and anti-p28 sera crossreacted with rat hepatocyte RHL-2/3 and its rat testis and sperm equivalent, galactosyl receptor, purified by chromatofocusing followed by galactose-Hydropore-EP affinity chromatography. Neither anti-p27 nor anti-p28 sera crossreacted with the major hepatocyte variant, RHL-1. A RHL-1-equivalent was not detected in rat testis and sperm. Immunofluorescence studies demonstrated that anti-p27 and anti-p28 sera recognize galactosyl receptor sites at the Sertoli cell-spermatogenic cell interface and on the dorsal surfacae of the sperm head, overlying the acrosome. The characteristic crescent-shaped immunoreactive pattern in sperm was lost after induction of the acrosome reaction. Further studies should determine whether antisera to MAP antigens 27-mer and 28-mer, corresponding to specific protein motifs, can serve as immunological probes for examining cell-cell interaction events during spermatogenesis and at fertilization. © 1995 Wiley-Liss, Inc.     

Differential ligand binding by two subunits of the rat liver asialoglycoprotein receptor

The rat liver asialoglycoprotein receptor consists of two typesof subunits, a predominant polypeptide designated rat hepaticlectin 1 (RHL-1) and a minor polypeptide, RHL-2/3, that comesin two differentially glycosylated forms. The exact stoichiometryand arrangement of the subunits in the RHL oligomer are notknown. The carbohydrate-recognition domain of RHL-2/ has beenprepared by limited proteolysis of the liver receptor so thatits properties can be compared with those of the correspondingdomain of RHL-1 previously produced in a bacterial expressionsystem. Binding studies indicate that while RHL-1 binds N-acetylgalactosaminewith approximately 60-fold higher affinity than it binds galactose,RHL-2/ has only 2-fold selectivity for N-acetylgalactosamine.In general, the pattern of monosaccharide-binding specificityfor RHL-2/ is similar to RHL-1, but the discrimination of varioussugars relative to galactose is reduced substantially. Limitedproteolysis and crosslinking studies demonstrate that RHL- 2/is easily removed from the RHL oligomer in detergent solutionand that RHL-1 remains at least trimeric following removal ofRHL-2/. These studies suggest that RHL-1 forms a ligand-bindingcore while RHL-2/ acts more as an accessory subunit contributingto selective binding of certain oligosaccharide structures. asialoglycoprotein receptor binding carbohydrate recognition lectin proteolysis     

Polarized expression of functional rat liver asialoglycoprotein receptor in transfected Madin-Darby canine kidney cells

The rat liver asialoglycoprotein receptor or rat hepatic lectin (RHL) consists of two polypeptide species, a major one designated RHL-1 and a minor one designated RHL-2/3, which exists in two differentially glycosylated forms. We have studied the biosynthesis, targeting, and function of the different forms after transfection of their cDNAs into the polarized Madin-Darby canine kidney cell line. In cells expressing only RHL-1, newly synthesized protein undergoes rapid intracellular degradation and is not detected at the cell surface. In contrast, RHL-2/3 when transfected alone is much more stable and is expressed at the basolateral surface of fiber-grown cells. When both forms are expressed together, newly synthesized RHL-1 escapes rapid degradation and is detected at the basolateral surface. In double transfectants a functional receptor is formed that specifically endocytoses and degrades ligand at the basolateral side.     

Structural similarity between the macrophage lectin specific for galactose/N-acetylgalactosamine and the hepatic asialoglycoprotein binding protein

The rat peritoneal macrophage lectin specific for galactose/N-acetylgalactosamine was shown to be a homologue of the hepatic asialoglycoprotein binding protein (rat hepatic lectin, RHL). The macrophage lectin was immunochemically crossreactive with the major form of RHL (RHL-1) but not with the minor forms (RHL-2 and -3). The overall homology between the macrophage lectin and RHL-1 was confirmed by peptide maps of their lysyl endopeptidase digests on reverse-phase HPLC. Despite these similarities, however, the macrophage lectin was distinct from HRL-1 as revealed by the differences in the NH2-terminal 20 amino acid sequences of these two lectins.     

Molecular cloning and sequence analysis of cDNA encoding the macrophage lectin specific for galactose and N-acetylgalactosamine

The primary structure of the macrophage lectin specific for galactose and N-acetylgalactosamine (macrophage asialoglycoprotein-binding protein, M-ASGP-BP) has been deduced from its cDNA sequence. The M-ASGP-BP cDNA encoded a protein consisting of 306 amino acid residues with a molecular mass of 34,242 daltons. The sequence was highly homologous with that of the rat liver asialoglycoprotein receptor (rat hepatic lectin, RHL), particularly that of RHL-1 (the major form of RHL), throughout its whole length, and especially so in its putative membrane-spanning region and carbohydrate recognition domain. There were two N-glycosylation sites in M-ASGP-BP, the location of which were identical to those in RHL-1. However, M-ASGP-BP was characteristic in having a shorter cytoplasmic tail, and an inserted segment of 24 amino acids containing an Arg-Gly-Asp sequence between the membrane-spanning region and carbohydrate recognition domain.     

Preparation of a high-affinity photolabeling reagent for the Gal/GalNAc lectin of mammalian liver: demonstration of galactose-combining sites on each subunit of rabbit hepatic lectin

On the basis of the knowledge that the D-galactose/N-acetyl-D-galactosamine-specific lectin of rabbit liver can tolerate a large group on the C-6 hydroxyl group of a galactoside [Lee, R. T. (1982) Biochemistry 21, 1045-1050], we prepared a high-affinity photolabeling reagent for this lectin from a triantennary glycopeptide fraction of asialofetuin. The C-6 hydroxyl group of a D-galactopyranoside was converted, under mild conditions, into a primary amino group. The procedure involves conversion of the hydroxyl group to an oxo group with galactose oxidase, followed by reductive amination using benzylamine and sodium cyanoborohydride. Catalytic hydrogenolysis of the benzylamino derivative yielded the desired 6-amino-6-deoxy-D-galactoside. A 4-azidobenzoyl group was attached to the newly produced amino group to yield a photoactivatable affinity-labeling reagent. The reagent labeled the Triton-solubilized, purified hepatic lectins of rabbit and rat in a photo- and affinity-dependent manner. All the polypeptide subunits of the lectins were labeled, indicating that each subunit contains at least one D-galactose-combining site. In the case of the rabbit hepatic lectin, the minor subunit (46 kDa) was labeled more efficiently than the major one (40 kDa).     

Affinity labeling of the galactose/N-acetylgalactosamine-specific receptor of rat hepatocytes: preferential labeling of one of the subunits

The galactose/N-acetylgalactosamine-specific receptor (also known as asialoglycoprotein receptor) of rat hepatocytes consists of three subunits, one of which [43 kilodalton (kDa)] exists in a greater abundance (up to 70% of total protein) over the two minor species (52 and 60 kDa). When the receptor on the hepatocyte membranes was photoaffinity labeled with an 125I-labeled high-affinity reagent [a triantennary glycopeptide containing an aryl azide group on galactosyl residues; Lee, R. T., & Lee, Y. C. (1986) Biochemistry 25, 6835-6841], the labeling occurred mainly (51-80%) on one of the minor bands (52 kDa). Similarly, affinity-bound, N-acetylgalactosamine-modified lactoperoxidase radioiodinated the same 52-kDa band preferentially. In contrast, both the photoaffinity labeling and lactoperoxidase-catalyzed iodination of the purified, detergent-solubilized receptor resulted in a distribution of the label that is comparable to the Coomassie blue staining pattern of the three bands; i.e., the 43-kDa band was the major band labeled. These and other experimental results suggest that the preferential labeling of the minor band and inefficient labeling of the major band on the hepatocyte membrane resulted from a specific topological arrangement of these subunits on the membranes. We postulate that in the native, membrane-bound state of the receptor, the 52-kDa minor band is topologically prominent, while the major (43 kDa) band is partially masked. This partial masking may result from a tight packing of the receptor subunits on the membranes to form a lattice work [Hardy, M. R., Townsend, R. R., Parkhurst, S. M., & Lee, Y. C. (1985) Biochemistry 24, 22-28].     

Purification and characterization of a human lectin specific for penultimate galactose residues

A novel lectin has been found in human plasma. The lectin was purified by affinity chromatography using an adsorbent in which 2-O-alpha-D-glucopyranosyl-O-beta-D-galactopyranosylhydroxylysine (Glc-Gal-Hyl) was coupled to Sepharose. The molecular weight of the lectin was determined by gradient gel electrophoresis to be approximately 240,000. On polyacrylamide gel electrophoresis in sodium dodecyl sulphate, the subunit had the molecular weight of 29,500. Composition analysis has shown the lectin is a glycoprotein in which 12% of the molecule consists of carbohydrate. Native human, horse, calf, sheep, rabbit, and rat erythrocytes were agglutinated by the lectin in the presence of calcium. Glc-Gal-Hyl, N-acetylated Glc-Gal-Hyl, and stachyose inhibited the hemagglutination, whereas monosaccharides, maltose, cellobiose, lactose, raffinose, galactosylhydroxylysine, and N-acetylated galactosylhydroxylysine were not inhibitory. The lectin is strongly inhibited by the desialylated bovine erythrocyte glycoprotein, which contains galactose beta 1-3galactose beta-sequence at the nonreducing termini of the sugar chains, whereas disialylated orosomucoid did not inhibit the lectin. These results indicate that the lectin recognizes the penultimate galactose residue in a hapten molecule in contrast to usual galactose-binding proteins or galactose-specific lectins, which recognize exposed, terminal galactose residues of sugar chains.     

The cell surface proteoglycan of mouse mammary epithelial cells. The extracellular domain contains N terminus and a peptide sequence present in a conditioned medium proteoglycan

The cell surface proteoglycan of mouse mammary epithelial (NMuMG) cells behaves as a receptor for interstitial matrix materials and consists of a membrane-associated domain and an extracellular domain (ectodomain). The ectodomain can be released intact from the cell surface by mild trypsin treatment and appears to be shed from the cells into the culture medium by cleavage from the membrane-associated domain. We have examined the chemical relationship between the trypsin-released proteoglycan and shed proteoglycan to assess their relationship to each other and to the cell surface. Purification and amino acid sequencing of the ectodomain released by mild trypsin treatment resulted in no clear signal until the protein was cleaved by CNBr treatment, suggesting that its N terminus is blocked and oriented extracellularly. The amino acid sequence identified in the trypsin-released ectodomain is present near the N terminus of the shed proteoglycan purified from conditioned medium, indicating that both forms possess closely related (if not identical) core proteins. The sequence reveals a pentapeptide identical to one near the C terminus of the rat hepatic lectin (RHL-1, rat asialoglycoprotein receptor). The medium proteoglycan, which migrates as a smear on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (between 93 and 200 kDa), is heterogeneous due to varying amounts of glycosaminoglycan and substituted O-linked oligosaccharide present on an approximately 46-kDa polypeptide.     

Biochemical and immunological characterization of A1 adenosine receptors purified from human brain membranes.

The A1 adenosine receptor was purified approximately 13,000-fold to apparent homogeneity from human cerebral cortex membranes using a novel affinity-chromatography system developed for the purification of rat brain and rat testis A1 adenosine receptors [Nakata, H. (1989) J. Biol. Chem. 264, 16,545-16,551; Nakata, H. (1990) J. Biol. Chem. 265, 671-677]. The purified human brain receptor showed the ligand-binding specificity expected of the A1 adenosine receptor. The Bmax and Kd for the purified receptor with a specific A1 adenosine receptor antagonist, 8-cyclopentyl-1,3-[3H]dipropylxanthine, were approximately 16 nmol/mg protein and 2 nM, respectively. SDS/PAGE of the purified receptor preparation showed one broad protein band of molecular mass of approximately 35 kDa, which is very similar to that of purified A1 adenosine receptor from rat brain membranes. Endoglycosidase F treatment of the purified receptor reduced the molecular mass to approximately 30 kDa, suggesting that the human brain A1 adenosine receptor is a glycoprotein. Comparison of the purified human and rat brain A1 adenosine receptors by peptide mapping after the proteolytic digestion showed minor differences between these receptors. Immunological comparisons of the human brain A1 adenosine receptor with rat brain A1 adenosine receptor using polyclonal antibodies against the purified rat brain A1 adenosine receptor showed that the antibodies react preferentially with the rat brain receptor and weakly with human brain receptor.     

Localization of epididymal secretory proteins on rat spermatozoa

Spermatozoa from the testis and cauda epididymidis of the rat were surface labelled with radioactive iodide. Detergent extracts of radioiodinated spermatozoa immunoprecipitated with antisera against specific epididymal proteins, followed by polyacrylamide gel electrophoresis, revealed two proteins (D and E of Mr 27 000 and 28 000, respectively) which became associated with spermatozoa during epididymal transit. These proteins were observed by immunofluorescence microscopy to be located over a restricted area of the head surface. Proteins with similar molecular weight were labelled on spermatozoa from the cauda epididymidis, but not from the testis, by reaction with sodium boro[3H]hydride in the presence of galactose oxidase. However, failure to immunoprecipitate with antibodies to Proteins D and E and non-coincident migration on two-dimensional gel electrophoresis established the non-identity of these proteins. Compared with Proteins D and E, two other major epididymal secretory proteins (Proteins B and C of Mr 16 000) associated with spermatozoa to a relatively minor extent during epididymal transit.     

Affinity purification of pancreastatin receptor-Gq/11 protein complex from rat liver membranes

Pancreastatin, a chromogranin A derived peptide, exerts a glycogenolytic effect on the hepatocyte. This effect is initiated by binding to membrane receptors which are coupled to pertussis toxin insensitive G proteins belonging to the Gq/11 family. We have recently solubilized active pancreastatin receptors from rat liver membranes still functionally coupled to G proteins. Here, we have purified pancreastatin receptors by a two-step procedure. First, pancreastatin receptors with their associated Gq/11 regulatory proteins were purified from liver membranes by lectin absorption chromatography on wheat germ agglutinin immobilized on agarose. A biotinylated rat pancreastatin analog was tested for binding to liver membranes before using it for affinity purification. Unlabeled biotinylated rat pancreastatin competed for 125I-labeled [Tyr0]PST binding to solubilized receptors with a Kd = 0.27 nM, comparable to that of native pancreastatin. The biotinylated analog was immobilized on streptavidin-coated Sepharose beads and used to further affinity purify wheat germ agglutinin eluted receptor material. Specific elution at low pH showed that the receptor protein was purified as an 80-kDa protein in association with a G protein of the q/11 family, as demonstrated by specific immunoblot analysis. The specificity of the receptor band was assessed by chemical cross-linking of the purified material followed by SDS-PAGE and autoradiography. In conclusion, we have purified pancreastatin receptor as a glycoprotein of 80 kDa physically associated with a Gq/11 protein.     

Multiplicity of heme oxygenase isozymes. HO-1 and HO-2 are different molecular species in rat and rabbit

We report on the detection and characterization of two forms of heme oxygenase in rabbit tissues and provide data suggesting that heme oxygenases in rat and rabbit are not identical and constitute a group of heterogenous proteins. Certain molecular properties, however, are shared by the isozymes in rat and rabbit; the predominant form of the enzyme in control liver and testis is HO-2, in the liver HO-1 is the inducible form, and in the brain HO-1 is not detectable. HO-1 was purified from liver of rabbits treated with bromobenzene to near homogeneity with a specific activity of 8,270 nmol of bilirubin/mg/h and compared with a homogenous preparation of rat HO-1 with a specific activity of 6,220, also obtained from bromobenzene-treated animals. Rat and rabbit HO-1, on sodium dodecyl sulfate-polyacrylamide gel, had molecular weights of 30,000 and 30,700, respectively. Rabbit HO-2 was partially purified from testis to a specific activity of 386 nmol of bilirubin/mg/h and compared with a purified preparation of rat testis HO-2 with a specific activity of 5,700. Using Western immunoblotting, rabbit HO-2 displayed intense cross-reactivity with antibody raised in rabbit to sodium dodecyl sulfate-denatured rat HO-2, and had a substantially larger molecular weight than the rat HO-2 (42,000 versus 36,000). Rabbit HO-1 did not cross-react with antibody to rat HO-1 which was also raised in rabbit. Unlike the rat enzymes, rabbit HO-1 and HO-2 did not differ in thermolability. It is speculated that HO-1 in rat and rabbit, and possibly HO-2, have evolved from divergent evolution of a common ancestral gene(s).     

A biologically active lectin of enteroaggregative Escherichia coli

The pathogenesis of enteroaggregative Escherichia coli, a major contributor to paediatric diarrhoea, is still not clearly understood. A complex carbohydrate specific lectin was identified from the culture supernatant of an enteroaggregative E. coli strain. The lectin was purified to 660-fold by a combination of sequential saturated ammonium sulphate precipitation and gel filtration chromatography in the FPLC system. The homogeneity of the purified lectin was established by analytical isoelectrofocusing [pI 6.75]. Hemagglutination of rabbit erythrocytes by the purified lectin was best inhibited by fetuin. The N-terminal sequence of the 41.7 kDa subunit showed homology to the outermembrane porins and the 23.4 kDa subunit showed homology to a hypothetical protein of Yersinia pestis and secreted Hcp protein. This protein could induce extensive morphological changes in HEp-2 cells and significant amount of fluid accumulation in rabbit ileal loop. GM1 showed maximum binding to the lectin among all other gangliosides. This purified protein showed cross-reactivity to the binding subunit of cholera toxin in western immunoblot. The presence of this toxin in some of the clinical isolates of enteroaggregative E. coli was also observed. The structural and functional characteristics of the toxin revealed that it is a novel virulence determinant of aggregative E. coli.     

Possible mechanism of entrapment of neuraminidase-treated lymphocytes in the liver

Neuraminidase-treated rat lymphocytes adhere strongly to rat hepatocytes in vitro. Binding between cells is due to stereo-specific interactions between a mammalian hepatic membrane lectin and galactosyl residues which are exposed on the lymphocyte surface after removal of sialic acid residues. The hepatic galactose specific lectin may play a role in the trapping of recirculating desialylated lymphocytes in the liver.     

Differential expression of asialoglycoprotein receptor subunits in the endocytic compartment during liver regeneration.

Asialoglycoprotein receptors, responsible for the removal of circulating asialoglycoproteins by the liver, are located in at least two different membrane locations in hepatocytes. Receptors on the cell surface account only for a minor proportion (20-36%), for the majority of receptors in the liver are located intracellularly, mainly in the endocytic membrane networks. An understanding of the basis of receptor distribution and the underlying trafficking of receptors between the hepatocyte's polarised cell surface and the endocytic compartment would be aided if biochemical differences between the receptors in these pools were established. We now show, using three antibodies that recognise the receptor subunits in rat liver (RHL-1, RHL-2 and RHL-3), that the asialoglycoprotein receptors located in the plasma membrane domains and the endocytic compartment differ in oligomeric composition, sialic acid content, and solubility in Triton X-114 using two-phase systems. It is well established that the expression of the asialoglycoprotein receptor is down-regulated in livers regenerating after a partial hepatectomy. We demonstrate that the levels of the receptor subtype that is located mainly in the endocytic compartment (RHL-1, 42 kDa) was elevated in regenerating liver by agents that regulate cAMP production, whereas the levels of the other receptor subtypes remained unchanged. The asialoglycoprotein receptor subtypes that are present in different subcellular locations are thus regulated independently.