Structural differences found in the sugar chains of eutopic and ectopic free alpha-subunits of human glycoprotein hormone

Pseudo-affinity chromatographic approach to probe heterogeneity in buffalo pituitary luteinizing hormone: probable pseudolectin-like behavior of immobilized Cibacron Blue 3GA

The alpha (α) and beta (β) subunits of buffalo pituitary luteinizing hormone (LH) were chromatographed on Cibacron Blue 3GA agarose and their immunoreactivity was quantitated using anti-α and anti-β anti sera. Subsequent analyses showed α subunits were relatively more hydrophilic than β subunits. Further, the naturally occurring free α and β subunits were more hydrophobic than their native counterparts which were dissociated and isolated from heterodimeric LH. The lesser sugar content in freely occurring α and beta subunits may be attributed for increased hydrophobicity and consequent upon the existence of their uncombined free forms. In order to ascertain putative sugar-dye interaction, crude LH carrying free subunits, pure LH, and non-glycosylated recombinant β subunit of LH were loaded separately on Cibacron Blue. Methyl mannoside was able to elute 33% of the bound protein in case of crude and pure LH, whereas there was little (3%) elution in case of recombinant LH β subunit. This study suggests a compositional heterogeneity in free and native subunits of LH from the buffalo pituitary. In addition, our findings reveal the pseudolectin-like behavior of Cibacron Blue.

Akira Kobata: a man who established the structural basis for glycobiology of N-linked sugar chains

Akira Kobata is a pioneer of the glycobiology of N-linked sugar chains. He established the basis of glycobiology by developing a series of reliable methods to analyse the structures of N-linked sugar chains. The sensitive methods established by him greatly contributed to our understanding of the structural characteristics of the sugar chains and the biosynthetic mechanisms responsible for the production of such characteristics. He also provided new aspects that the sugar chains of glycoproteins play an important role in cell-to-cell recognition, and that the structures of sugar chains are altered under physiological and pathological conditions, including many tumours and diseases on a structural basis. In this article, the author would like to sketch out Kobata's main contributions to glycobiology for the sake of young scientists, who are planning to enter this scientific field in the future.

Rapid Maturation of Glycoprotein Hormone Free α-Subunit (GPHα) and GPHαα Homodimers

The dynamics of glycoprotein hormone α-subunit (GPHα) maturation and GPHαα homodimer formation were studied in presence (JEG-3 choriocarcinoma cells) and absence (HeLa cells) of hCGβ. In both cases, the major initially occurring GPHα variant in [35S]Met/Cys-labeled cells carried two N-glycans (Mr app = 22 kDa). Moreover, a mono-N-glycosylated in vivo association-incompetent GPHα variant (Mr app = 18 kDa) was observed. In JEG-3 cells the early 22-kDa GPHα either associated with hCGβ, or showed self-association to yield GPHαα homodimers, or was later converted into heavily glycosylated large free GPHα (Mr app = 24 kDa). Micro-preparative isolation of intracellular GPHαα homodimers of JEG-3 cells and their conversion by reduction revealed that they consisted of 22-kDa GPHα monomers and not of large free GPHα. In HeLa cells, the large free GPHα variant was not observed, whereas GPHαα homodimers were present. Intracellularly, early GPHαα homodimers (35 kDa) and late variants (JEG-3: 44 kDa, HeLa: 39 kDa) were found. Both cell types secreted 45 kDa GPHαα homodimers. Large free GPHα and GPHαα homodimers were more rapidly sialylated than hCG αβ-heterodimers indicating a sequestration mechanism in the secretory pathway. In GPHαα homo- as well as hCG αβ-heterodimers the subunit interaction site, located on loop 2 of GPHα (amino acids 33–42), became immunologically inaccessible indicating similar spatial orientation of GPHα in both types of dimers. The studies demonstrate the formation, in vivo dynamics of GPHαα homodimers, and the pathways of the cellular metabolism of variants of GPHα, monoglycosylated GPHα and large free GPHα.

Structure, pathology and function of the N-linked sugar chains of human chorionic gonadotropin

Human chorionic gonadotropin (hCG) contains five acidic N-linked sugar chains, which are derived from three neutral oligosaccharides by sialylation. Each of the two subunits (hCGalpha and hCGbeta) of hCG contain two glycosylated Asn residues. Glycopeptides, each containing a single glycosylated Asn, were obtained by digestion of hCGalpha with trypsin, and of hCGbeta with chymotrypsin and lysyl endopeptidase. Comparative study of the sugar chains of the four glycopeptides revealed the occurrence of site-directed glycosylation. Studies of the sugar chains of hCGs, purified from urine of patients with various trophoblastic diseases, revealed that choriocarcinoma hCGs contain sialylated or non-sialylated forms of eight neutral oligosaccharides. In contrast, hCGs from invasive mole patients contain sialyl derivatives of five neutral oligosaccharides. The structural characteristics of the five neutral oligosaccharides, detected in choriocarcinoma hCGs but not in normal placental hCGs, indicate that N-acetylglucosaminyltransferase IV (GnT-IV) is abnormally expressed in the malignant cells. This supposition was confirmed by molecular biological study of GnT-IV in placenta and choriocarcinoma cell lines. The appearance of tumor-specific sugar chains in hCG has been used to develop a diagnostic method of searching for malignant trophoblastic diseases. In addition, a summary of the current knowledge concerning the functional role of N-linked sugar chains in the expression of the hormonal activity of hCG has been presented.

Solution structure of the alpha-subunit of human chorionic gonadotropin

The three-dimensional solution structure of the alpha-subunit in the alpha, beta heterodimeric human chorionic gonadotropin (hCG), deglycosylated with endo-beta-N-acetylglucosaminidase-B (dg-alpha hCG), was determined using 2D homonuclear and 2D heteronuclear 1H, 13C NMR spectroscopy at natural abundance in conjunction with the program package XPLOR. The distance geometry/simulated annealing protocol was modified to allow for the efficient modelling of the cystine knot motif present in alpha hCG. The protein structure was modelled with 620 interproton distance restraints and the GlcNAc residue linked to Asn78 was modelled with 30 protein-carbohydrate and 3 intraresidual NOEs. The solution structure of dg-alpha hCG is represented by an ensemble of 27 structures. In comparison to the crystal structure of the dimer, the solution structure of free dg-alpha hCG exhibits: (a) an increased structural disorder (residues 33-57); (b) a different backbone conformation near Val76 and Glu77; and (c) a larger flexibility. These differences are caused by the absence of the interactions with the beta-subunit. Consequently, in free dg-alpha hCG, compared to the intact dimer, the two hairpin loops 20-23 and 70-74 are arranged differently with respect to each other. The beta-GlcNAc(78) is tightly associated with the hydrophobic protein-core in between the beta-hairpins. This conclusion is based on the NOEs from the axial H1, H3, H5 atoms and the N-acetyl protons of beta-GlcNAc(78) to the protein-core. The hydrophobic protein-core between the beta-hairpins is thereby shielded from the solvent.

Developmental changes in the glycosylation of glycoprotein hormone free alpha subunit during pregnancy

Glycoprotein hormone alpha subunit, in its free form (free alpha), is a major placental product. Its glycosylation was found to change dramatically during the advancement of pregnancy. In this study, we have analyzed these glycosylation changes in five normal pregnancies. Binding to Lens culinaris lectin increased dramatically in all subjects between weeks 14 and 17 from the last menstrual period, indicating more core fucosylation as well as possible changes in branching of glycans. Studies using Datura stramonium agglutinin confirmed that the type of triantennary branching changed in this period of pregnancy. The precise structural nature of these changes was determined by high-pH anion-exchange chromatography and electrospray ionization mass spectrometry. Amounts of core fucosylation and of triantennary glycans increased substantially from early to late second trimester, and a shift was observed from 1-->4/1-->3- toward predominantly 1-->6/1-->6-branched triantennary structures. The glycosylation changes occurred in all five individuals at the same time period in gestation, suggesting developmental regulation of N-acetylglucosaminyltransferases IV and V and alpha6-fucosyltransferase during normal pregnancy. These enzymatic activities also appear to be affected in malignant transformation of the trophoblast. Our findings have important implications for the proposed use of specific forms of glycosylation as markers for cancer, as the relative amounts of these glycans in normal pregnancy will be determined by gestational age.

Altered glycosylation of beta 1 integrins associated with reduced adhesiveness to fibronectin and laminin

The carbohydrate structures of the beta 1 integrins obtained from a mouse metastatic melanoma B16 F1 and its weakly metastatic wheat-germ agglutinin-resistant mutant Wa4-b1 were studied comparatively. The results indicated that the integrins from both cells contain high mannose-type and bi-, tri- and tetra-antennary complex-type sugar chains. No significant difference was found in the outer chain branching between both integrins, but sialylation of the sugar chains of the mutant's integrin was markedly decreased and almost all the outer chain moieties of tri- and tetra-antennary oligosaccharides of the mutant's integrin were fucosylated, resulting in the formation of X-antigenic determinants, Gal beta 1-->4 (Fuc alpha 1-->3) GlcNAc. In contrast, the integrin from parental cell contained no X-antigenic determinant. These structural differences found in the integrin are thought to account for the reduction in the metastatic potential of the mutant which also shows reduced adhesion to fibronectin and laminin as compared with the parental cell.

Molecular structures of glycoprotein hormones and functions of their carbohydrate components

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Structures and functions of the sugar chains of glycoproteins

Most proteins within living organisms contain sugar chains. Recent advancements in cell biology have revealed that many of these sugar chains play important roles as signals for cell-surface recognition phenomena in multi-cellular organisms. In order to elucidate the biological information included in the sugar chains and link them with biology, a novel scientific field called 'glycobiology' has been established. This review will give an outline of the analytical techniques for the structural study of the sugar chains of glycoproteins, the structural characteristics of the sugar chains and the biosynthetic mechanism to produce such characteristics. Based on this knowledge, functional aspects of the sugar chains of glycohormones and of those in the immune system will be described to help others understand this new scientific field.

Structures of the asparagine-linked sugar chains of human chorionic gonadotropin from a patient with extragonadal germ cell tumour

Human chorionic gonadotropin (hCG) purified from the urine of a male patient with extragonadal germ cell tumour contained four asparagine-linked sugar chains in one molecule. The sugar chains were quantitatively released from the polypeptide moiety by hydrazinolysis and recovered as oligosaccharides after N-acetylation. The oligosaccharide mixture was separated into a neutral (N) and three acidic (A1, A2 and A3) fractions by anion-exchange column chromatography. By sequential exoglycosidase digestion, methylation analysis and lectin column chromatography, the structures of these oligosaccharides were found to be the same as those of female gestational choriocarcinoma hCGs. Both contain eight kinds of sugar chains: triantennary, abnormal and normal biantennary, and monoantennary complex-type sugar chain with or without a fucosylated core portion.

cDNA-derived amino acid sequences of choriocarcinoma alpha- and beta-subunits of human choriogonadotropin

Although amino acid sequences of the alpha- and beta-subunits of human choriogonadotropin (hCG) are known, only limited information is available on the disease state hCG. We have examined the amino acid sequences of the alpha- and beta-subunits of hCG from choriocarcinoma BeWo cells. The amino acid sequences were derived from the nucleotide sequences of BeWo cDNA clones of hCG alpha- and beta-subunits and were found to be identical with those of the normal subunits. It appears that the differences between the normal and the choriocarcinoma alpha- and beta-subunits of hCG reside primarily in the carbohydrates rather than the amino acid sequences. It may be pointed out that although coding and non-coding regions of BeWo cDNA clones of CG alpha and CG beta had several base changes from the hCG alpha and hCG beta cDNAs, these changes did not result in the alteration of their amino acid sequences. The longest BeWo alpha and beta cDNAs were 719 and 878 base pairs (bp) in length and lacked only 16 and 7 bp from the transcription start sites respectively. BeWo CG alpha cDNA had two base changes in the non-coding regions, one insertion of C at position 39 and another substitution of T for A at position 651, the latter change deleted one HindIII polymorphous site. The BeWo CG beta cDNA also had two base substitutions, A for G at 131 in the non-coding region and T for C at 807 position in the coding region.