Tritiation of endotoxin.

Tritiated endotoxin was synthesized by three different methods: (1) sodium boro[3H]hydride reduction of native endotoxin; (2) sodium boro[3H]hydride reduction of endotoxin that had been oxidized previously with sodium metaperiodate; and (3) exposure of dry endotoxin to 3H2 gas. Sodium borohydride reduces aldehyde groups and sodium metaperiodate oxidizes vicinal glycol groups to aldehydes. Chromatographic analysis of the three tritiated endotoxins, using agarose, revealed that the biological activity associated with each labeled product appeared at the void volume, and in each case the biological activity coincided with a peak in radioactivity. The labeled product of the first method had a specific radioactivity of 0.18 mCi/g and a biological activity equal to that of native endotoxin. The labeled products of the second and third methods had specific activities of 2.1 mCi/g and 60.0 mCi/g, respectively, while their biological activities were one hundred-fold less than native endotoxin, as determined by the Limulus amebocyte lysate assay. These three labeled endotoxins are potentially ueled endotoxin.     

Deglycosylation of glycoproteins

Glycosylation procedures and their application for the elucidation of glycoprotein structure and structure-function relations, as well as for the development of analytical systems for clinical practice are reviewed. For some common cases found in research practice, the choice of optimal deglycosylation methods is discussed. Current views on the primary structure of glycoproteins are described briefly.     

Bacterial glycoproteins

Glycoproteins are a diverse group of complex macromolecules that are present in virtually all forms of life. Their presence in prokaryotes, however, has been demonstrated, and accepted, only recently. Bacterial glycoproteins have been identified in many archaeobacteria and in eubacteria. They comprise a wide range of different cell envelope components such as membrane-associated glycoproteins, surface-associated glycoproteins and crystalline surface layers (S-layers), as well as secreted glycoproteins and exoenzymes. Even their occurrence in the cytoplasm cannot yet be ruled out. This minireview tries to cover the whole subject as completely as possible and refers to available information on presence, structure, biosynthesis, and molecular biology of bacterial glycoproteins.     

Antifreeze glycoproteins

Antifreeze glycoproteins (AFGPs) are a novel class of biologically significant compounds that possess the ability to inhibit the growth of ice both in vitro and in vivo. Any organic compound that possesses the ability to inhibit the growth of ice has many potential medical, industrial, and commercial applications. In an effort to elucidate the molecular mechanism of action, various spectroscopic and physical techniques have been used to investigate the solution conformations of these glycoproteins. This review examines the characterization of AFGPs and potential biological applications relating to stabilization of lipid membranes and vitrification adjuvants.     

Tailor-made glycoproteins

Posttranslational modifications are a fundamental mechanism for the regulation of cellular physiology and function. A recent paper by Zhang et al. provides a novel strategy for the generation of homogeneous glycoproteins. The ability to install covalent modifications site-specifically into proteins holds tremendous promise for deciphering the role of posttranslational modifications and has exciting implications for the development of protein therapeutics.     

Lysosomal metabolism of glycoproteins

The lysosomal catabolism of glycoproteins is part of the normal turnover of cellular constituents and the cellular homeostasis of glycosylation. Glycoproteins are delivered to lysosomes for catabolism either by endocytosis from outside the cell or by autophagy within the cell. Once inside the lysosome, glycoproteins are broken down by a combination of proteases and glycosidases, with the characteristic properties of soluble lysosomal hydrolases. The proteases consist of a mixture of endopeptidases and exopeptidases, which act in concert to produce a mixture of amino acids and dipeptides, which are transported across the lysosomal membrane into the cytosol by a combination of diffusion and carrier-mediated transport. Although the glycans of all mature glycoproteins are probably degraded in lysosomes, the breakdown of N-linked glycans has been studied most intensively. The catabolic pathways for high-mannose, hybrid, and complex glycans have been established. They are bidirectional with concurrent sequential removal of monosaccharides from the nonreducing end by exoglycosidases and proteolysis and digestion of the carbohydrate-polypeptide linkage at the reducing end. The process is initiated by the removal of any core and peripheral fucose, which is a prerequisite for the action of the peptide N-glycanase aspartylglucosaminidase, which hydrolyzes the glycan-peptide bond. This enzyme also requires free alpha carboxyl and amino groups on the asparagine residue, implying extensive prior proteolysis. The catabolism of O-linked glycans has not been studied so intensively, but many lysosomal glycosidases appear to act on the same linkages whether they are in N- or O-linked glycans, glycosaminoglycans, or glycolipids. The monosaccharides liberated during the breakdown of N- and O-linked glycans are transported across the lysosomal membrane into the cytosol by a combination of diffusion and carrier-mediated transport. Defects in these pathways lead to lysosomal storage diseases. The structures of some of the oligosaccharides that accumulate in these diseases are not digestion intermediates in the lysosomal catabolic pathways but correspond to intermediates in the biosynthetic pathway for N-linked glycans, suggesting another route of delivery of glycans to the lysosome. Incorrectly folded or glycosylated proteins that are rejected by the quality control mechanism are broken down in the ER and cytoplasm and the end product of the cytosolic degradation of N-glycans is delivered to the lysosomes. This route is enhanced in cells actively secreting glycoproteins or producing increased amounts of aberrant glycoproteins. Thus interaction between the lysosome and proteasome is important for the regulation of the biosynthesis and distribution of N-linked glycoproteins. Another example of the extralysosomal function of lysosomal enzymes is the release of lysosomal proteases into the cytosol to initiate the lysosomal pathway of apoptosis.     

Zona pellucida glycoproteins

All mammalian eggs are surrounded by a relatively thick extracellular coat, the zona pellucida, that plays vital roles during oogenesis, fertilization, and preimplantation development. The mouse zona pellucida consists of three glycoproteins that are synthesized solely by growing oocytes and assemble into long fibrils that constitute a matrix. Zona pellucida glycoproteins are responsible for species-restricted binding of sperm to unfertilized eggs, inducing sperm to undergo acrosomal exocytosis, and preventing sperm from binding to fertilized eggs. Many features of mammalian and non-mammalian egg coat polypeptides have been conserved during several hundred million years of evolution.