Absolute molecular weight distribution of low-molecular-weight heparins by size-exclusion chromatography with multiangle laser light scattering detection.

The absolute molecular weight (M(r)) distribution of seven low-molecular-weight (LMW) heparin products was determined by size-exclusion chromatography (SEC) coupled with multiangle laser light scattering (MALLS) detection. The SEC/MALLS technique does not rely on relative M(r) standards for column calibration and yields absolute M(r) estimates directly from the angular dependence of scattered light intensity as a function of concentration, as formulated by light scattering theory. The SEC/MALLS method we describe is rapid, precise, and accurate. In 1 h it yields results from triplicate injections that agree well with the manufacturers' own independent analyses and that exhibit coefficients of variation of approximately 1%. By eliminating the requirement for finite quantities of highly purified, well-characterized M(r) standards derived from heparin, the present procedure represents a clear improvement over relative methods of M(r) determination. Thus, it is concluded that the SEC/MALLS method is ideally suited to routine quality control of commercial LMW-heparin products.

Identification of structural features of heparin required for inhibition of herpes simplex virus type 1 binding.

Binding of HSV-1 to cells is mediated by interactions of virion glycoproteins gC and/or gB with heparin sulfate (HS) glycosaminoglycans on cell surface proteoglycans. HS and the related glycosaminoglycan, heparin, comprise a family of heterogeneous carbohydrates composed of long, unbranched polysaccharides modified, for example, by sulfations and acetylations. To define the specific features of HS important for viral binding, we took advantage of the structural similarities between heparin and cell surface HS and compared the ability of chemically modified heparin compounds to inhibit the binding of viral particles to the cell surface and subsequent plaque formation. Because binding presumably involves multiple, complex interactions between both known heparin-binding glycoproteins, gC and gB, and cell surface HS, we compared the effects of modified heparin compounds on the binding and subsequent plaque formation of wild-type and gC-negative strains of HSV-1 and, in select cases, the binding of gB-negative virus to cells. We identified specific structural features of heparin essential for the inhibition of viral binding. For example, both N-sulfation and 6-O-sulfation must be important determinants since desulfation of heparin at these sites abolished or decreased the antiviral activity of heparin. Moreover, we found that the antiviral activity of heparin was independent of its anticoagulant activity. Carboxyl-reduced and 2,3-O-desulfated heparin selectively inhibited binding of gC-positive viruses (wild-type or a gB-negative strain) to cells, but had little or no inhibitory effect on binding and subsequent plaque formation for a gC-deletion virus. These results suggest that gC and gB interact with different structural features of HS.

Structural features in heparin which modulate specific biological activities mediated by basic fibroblast growth factor.

The biological activity of basic fibroblast growth factor (bFGF) is influenced greatly by direct binding to heparin and heparan sulphate (HS). Heparin-derived oligosaccharides have been utilized to determine the structural requirements present in the polymer that account for binding to bFGF. We had previously demonstrated that fragments > 6 mer can inhibit the interaction between cell surface heparan sulphate proteoglycan (HSPG) and bFGF, and bFGF-induced proliferation of adrenocortical endothelial (ACE) cells. In contrast, oligosaccharides > 10 mer can enhance the binding of bFGF to its high-affinity receptor or support bFGF-induced mitogenesis in ACE cells (Ishihara et al., J. Biol. Chem., 268, 4675-4683, 1993). We have extended these studies to size- and structure-defined oligosaccharides from heparin, 2-O-desulphated (2-O-DS-) heparin, 6-O-desulphated (6-O-DS-) heparin, carboxy-reduced (CR-) heparin and carboxy-amidomethylsulphonated (AMS-) heparin. Oligosaccharides from these polymers were fractionated on a bFGF-affinity column and were assessed as inhibitors or enhancers of specific bFGF-derived biological activities. The results of these studies indicate that both 2-O-sulphate and the negative charge of the carboxy group [L-iduronic acid (IdoA) residues] are required for specific interactions of heparin-derived oligosaccharides with bFGF and for modulation of bFGF mitogenic activity. In addition, the charge of the carboxy groups in uronic acids can be replaced by other functional groups with a negative charge, such as the amidomethyl sulphonate moiety described here.

Reversion of Q beta RNA phage mutants by homologous RNA recombination.

Q beta phage RNAs with inactivating insertion (8-base) or deletion (17-base) mutations within their replicase genes were prepared from modified Q beta cDNAs and transfected into Escherichia coli spheroplasts containing Q beta replicase provided in trans by a resident plasmid. Replicase-defective (Rep-) Q beta phage produced by these spheroplasts were detected as normal-sized plaques on lawns of cells containing plasmid-derived Q beta replicase, but were unable to form plaques on cells lacking this plasmid. When individual Rep- phage were isolated and grown to high titer in cells containing plasmid-derived Q beta replicase, revertant (Rep+) Q beta phage were obtained at a frequency of ca. 10(-8). To investigate the mechanism of this reversion, a point mutation was placed into the plasmid-derived Q beta replicase gene by site-directed mutagenesis. Q beta mutants amplified on cells containing the resultant plasmid also yielded Rep+ revertants. Genomic RNA was isolated from several of the latter phage revertants and sequenced. Results showed that the original mutation (insertion or deletion) was no longer present in the phage revertants but that the marker mutation placed into the plasmid was now present in the genomic RNAs, indicating that recombination was one mechanism involved in the reversion of the Q beta mutants. Further experiments demonstrated that the 3' noncoding region of the plasmid-derived replicase gene was necessary for the reversion-recombination of the deletion mutant, whereas this region was not required for reversion or recombination of the insertion mutant. Results are discussed in terms of a template-switching model of RNA recombination involving Q beta replicase, the mutant phage genome, and plasmid-derived replicase mRNA.

Similar conformers in the minus strands of divergent positive strand RNA phage.

Minus strand RNAs of phages MS2 and Q beta, prepared by in vitro transcription, were each separated into two forms on nondenaturing agarose gels. Only a single form of RNA was observed for minus strands denatured with glyoxal prior to agarose analysis, demonstrating that the two forms were conformers in each case. Truncated and elongated versions of these RNAs, analyzed under nondenaturing conditions, demonstrated that a region of RNA complementary to the A protein gene was at least partially responsible for the presence of these conformers in both MS2 and Q beta minus strands.

Negative-strand RNA replication by Q beta and MS2 positive-strand RNA phage replicases.

Plasmids were constructed which allowed preparation of positive- and negative-strand MS2 RNA by in vitro transcription and which expressed the MS2 phage replicase. Transcribed, positive-strand MS2 RNA was infectious to Escherichia coli spheroplasts. Transcribed, negative-strand MS2 RNA was infectious to spheroplasts containing either MS2 replicase or related bacteriophage Q beta replicase.

Infectious positive- and negative-strand transcript RNAs from bacteriophage Q beta cDNA clones.

Plasmids containing full-length cDNA copies of the Q beta RNA phage genome and flanking T7 promoters were constructed. Positive-strand Q beta RNA, generated by in vitro transcription of these plasmids with T7 RNA polymerase, was infectious to Escherichia coli spheroplasts. The Q beta replicase gene from the cloned DNA was subcloned and expressed in E. coli cells by means of a thermoinducible plasmid. Full-length, negative-strand Q beta transcripts were infectious when transfected into spheroplasts containing the induced replicase gene.

The disaccharides formed by deaminative cleavage of N-deacetylated glycosaminoglycans.

Chondroitin 4-sulphate, chondroitin 6-sulphate, dermatan sulphate and keratan sulphate were N-deacetylated by treatment with hydrazine and then cleaved with HNO2 at pH 4.0, and the resulting products were reduced with NaB3H4. This reaction sequence cleaved the glycosaminoglycans at their N-acetyl-D-glucosamine or N-acetyl-D-galactosamine residues, which were converted into 3H-labelled 2,5-anhydro-D-mannitol (AManR) or 2,5-anhydro-D-talitol (ATalR) residues respectively. The end-labelled disaccharides, composed of D-glucuronic acid (GlcA), L-iduronic acid (IdoA) or D-galactose (Gal) and one of the anhydrohexitols, were identified as follows: both chondroitin 4-sulphate and chondroitin 6-sulphate gave GlcA----ATalR(4-SO4), GlcA----ATalR(6-SO4), IdoA----ATalR (4-SO4) and GlcA(2-SO4)----ATalR(6-SO4); dermatan sulphate gave IdoA----ATalR(4-SO4), GlcA----ATalR(4-SO4), GlcA----ATalR(6-SO4)----IdoA(2-SO4)ATalR(4-SO4) and IdoA----ATalR (4,6-diSO4); keratan sulphate gave Gal(6-SO4)----AManR(6-SO4), Gal----AManR(6-SO4), Gal(6-SO4)----AManR and Gal----AManR. Several additional disaccharides were generated by treatment of the uronic acid-containing disaccharides with hydrazine to epimerize their uronic acid residues at C-5. A number of these disaccharides were found to be substrates for lysosomal sulphatases and glycuronidases. Methods were developed for the separation of all of the disaccharide products by h.p.l.c. The rate of N-deacetylation of chondroitin 4-sulphate by hydrazinolysis was significantly lower than the rate of N-deacetylation of chondroitin 6-sulphate or chondroitin. Dermatan sulphate was N-deacetylated at an intermediate rate. The relative amounts of disaccharides obtained from chondroitin 4-sulphate, chondroitin 6-sulphate and dermatan sulphate under optimum hydrazinolysis/deamination conditions were comparable with the amounts of the corresponding products released from the polymers by chondroitinase treatment.

Structural changes in the large proteoglycan in differentiating chondrocytes from the chick embryo tibiotarsus.

35SO4(2-)- or [3H]GlcN-labeled heavy proteochondroitin sulfate was isolated from monolayer cultures of chondrocytes from the zones of dividing, elongated, and hypertrophying cells of chick embryo tibias, and the keratan sulfate (KS) component was characterized. The KS glycopeptides remaining after digestion of the proteoglycans with thermolysin and chondroitinases were isolated and depolymerized by hydrazinolysis and nitrous acid cleavage. The resulting KS disaccharides had nonreducing terminal D-galactose (Gal) residues and reducing terminal anhydro-D-mannose (AMan) residues. The KS fractions from all cultures had identical disaccharide compositions, with 18-20% Gal----AMan, 72-79% Gal----AMan(6-SO4), and 7-9% Gal(6-SO4)----AMan(6-SO4). The ratios of chondroitin sulfate (CS) to KS synthesized by cultures of dividing, elongated, and hypertrophied chondrocytes were 15, 27, and 30, respectively. Approximately 30% of the CS chains of the proteochondroitin sulfate in the cell matrix pools had nonreducing terminal GalNAc(4,6-diSO4) residues, but none of the CS chains in the proteochondroitin sulfate recovered from the culture medium pools were terminated with these residues.

A sulfatase specific for glucuronic acid 2-sulfate residues in glycosaminoglycans.

Although 2-O-sulfated L-iduronic acid (IdoA) residues have been known to occur in heparin, 2-O-sulfated D-glucuronic acid (GlcA) residues have been reported only recently (Bienkowski, M. J., and Conrad, H. E. (1985) J. Biol. Chem. 250, 356-365). Disaccharides prepared by cleavage of heparin and N-deacetylated chondroitin 6-sulfate with nitrous acid were used to demonstrate a new sulfatase that catalyzed the removal of the 2-O-sulfate substituents from GlcA but not IdoA residues. The deamination products were labeled by NaB3H4 reduction to give disaccharides from heparin and chondroitin sulfate which had reducing terminal 2,5-anhydro-D-mannitol ([3H]AManR) and 2,5-anhydro-D-talitol ([3H]ATalR) residues, respectively. IdoA(2-SO4)-[3H]AManR(6-SO4) from heparin and GlcA(2-SO4)-[3H]ATalR(6-SO4) from chondroitin sulfate were purified for use as substrates. GlcA(2-SO4)-[3H]AManR(6-SO4) was prepared by epimerization of IdoA(2-SO4)-[3H]AManR(6-SO4) with hydrazine at 100 degrees C. Lysosomal enzyme preparations from chick embryo chondrocytes and from two normal human fibroblast cell lines catalyzed the removal of the 2-O-SO4 substituent from the uronic acid residues of IdoA(2-SO4)-[3H]AManR(6-SO4), GlcA(2-SO4)-[3H] AManR(6-SO4), and GlcA(2-SO4)-[3H]ATalR(6-SO4). In contrast, a lysosomal enzyme preparation from a human fibroblast cell line deficient in idurono-2-sulfatase (Hunter's-syndrome), which had no activity on the IdoA(2-SO4)-[3H]AManR(6-SO4), converted GlcA(2-SO4)-[3H]AManR(6-SO4) to a mixture of GlcA-[3H] AManR(6-SO4) and [3H]AManR(6-SO4). This enzyme also converted GlcA(2-SO4)-[3H]ATalR(6-SO4) to a mixture of GlcA-[3H]ATalR(6-SO4) and [3H]ATalR(6-SO4). Digestion of both GlcA(2-SO4)-[3H]AManR(6-SO4) and GlcA(2-SO4)-[3H]ATalR(6-SO4) was inhibited by 35SO2-4 and was arrested at the monosulfated disaccharide stage by 1,4-saccharolactone. The glucurono-2-sulfatase exhibited a pH optimum of 4. The results indicate that there exists a separate sulfatase for the removal of sulfate substituents from C-2 of GlcA residues in glycosaminoglycans.

Hydrazinolysis of heparin and other glycosaminoglycans.

Heparin, carboxy-group-reduced heparin, several sulphated monosaccharides and disaccharides formed from heparin, and a tetrasaccharide prepared from chondroitin sulphate were treated at 100 degrees C with hydrazine containing 1% hydrazine sulphate for periods sufficient to cause complete N-deacetylation of the N-acetylhexosamine residues. Under these hydrazinolysis conditions both the N-sulphate and the O-sulphate substituents on these compounds were completely stable. However, the uronic acid residues were converted into their hydrazide derivatives at rates that depended on the uronic acid structures. Unsubstituted L-iduronic acid residues reacted much more slowly than did unsubstituted D-glucuronic acid or 2-O-sulphated L-iduronic acid residues. The chemical modification of the carboxy groups resulted in a low rate of C-5 epimerization of the uronic acid residues. The hydrazinolysis reaction also caused a partial depolymerization of heparin but not of carboxy-group-reduced heparin. Treatment of the hydrazinolysis products with HNO2 at either pH 4 or pH 1.5 or with HIO3 converted the uronic acid hydrazides back into uronic acid residues. The use of the hydrazinolysis reaction in studies of the structures of uronic acid-containing polymers and the implications of the uronic acid hydrazide formation are discussed.