Poly(ethylene glycol) (PEG) was incorporated into multivalent conjugates of the N-terminal domain of beta(2)GPI (domain 1). PEG was incorporated to reduce the rate of elimination of the conjugates from plasma and to putatively improve their efficacy as toleragens for the suppression of anti-beta(2)GPI antibodies and the treatment of antiphospholipid syndrome (APS). Three structurally distinct types of multivalent platforms were constructed by incorporating PEG into the platform structures in different ways. The amount of PEG incorporated ranged from about 5000 g per mole to about 30000 g per mole. The platforms were functionalized with either four or eight aminooxy groups. The conjugates were prepared by forming oxime linkages between the aminooxy groups and N-terminally glyoxylated domain 1 polypeptide. The plasma half-life of each conjugate, labeled with (125)I, was measured in both mice and rats. The half-lives of the conjugates ranged from less than 10 min to about 1 h in mice, and from less than 3 h to about 19 h in rats. The ability of five tetravalent conjugates to suppress anti-domain 1 antibodies in immunized rats was also measured. Incorporation of PEG in the conjugates significantly reduced the doses required for suppression, and the amount of reduction correlated with the amount of PEG incorporated.
Human low-density lipoprotein (LDL) was glucosylated by incubation in vitro with glucose (20-80 mM) with or without addition of cyanoborohydride. The incorporation of covalently bound glucose was linear over time, and amino acid analysis showed the presence of glucosyllysine residues. The glucosylated LDL (glc LDL) moved more rapidly than normal LDL on agarose electrophoresis. The rate of degradation of 125I-labeled glucosylated LDL (glc LDL) by cultured human fibroblasts was reduced compared with that of native I-LDL, the difference increasing with extent of glucosylation. Effects were seen with blockage of as few as 6-15% of the LDL lysine residues; high-affinity degradation was completely lost when one-third of the lysine residues were blocked. Conjugation of LDL with glucose-6-phosphate also blocked high-affinity uptake and degradation. Whereas native LDL uptake inhibited the activity of beta-hydroxy-beta-methylglutaryl coenzyme A reductase and stimulated acyl coenzyme A:cholesterol acyltransferase activity, glc LDL had no effects on these enzymes. The fractional catabolic rate of glc LDL in guinea pigs was reduced. Degradation of glc LDL by mouse peritoneal macrophages was not significantly faster than that of native LDL. Finally, the presence of glc LDL in human plasma was demonstrated. Preliminary data show that 1.3% of lysine residues in normal LDL and 2-5.3% of lysines in diabetic LDL were glucosylated. Since, like other plasma proteins, LDL undergoes glucosylation in diabetes, its turnover and sites of catabolism may differ from normal and this may be relevant to the accelerated atherosclerosis of diabetes.
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