Molecular organization of the alkali-insoluble fraction of Aspergillus fumigatus cell wall

Physical and biological properties of the fungal cell wall are determined by the composition and arrangement of the structural polysaccharides. Cell wall polymers of fungi are classically divided into two groups depending on their solubility in hot alkali. We have analyzed the alkali-insoluble fraction of the Aspergillus fumigatus cell wall, which is the fraction believed to be responsible for fungal cell wall rigidity. Using enzymatic digestions with recombinant endo-beta-1,3-glucanase and chitinase, fractionation by gel filtration, affinity chromatography with immobilized lectins, and high performance liquid chromatography, several fractions that contained specific interpolysaccharide covalent linkages were isolated. Unique features of the A. fumigatus cell wall are (i) the absence of beta-1,6-glucan and (ii) the presence of a linear beta-1, 3/1,4-glucan, never previously described in fungi. Galactomannan, chitin, and beta-1,3-glucan were also found in the alkali-insoluble fraction. The beta-1,3-glucan is a branched polymer with 4% of beta-1,6 branch points. Chitin, galactomannan, and the linear beta-1, 3/1,4-glucan were covalently linked to the nonreducing end of beta-1, 3-glucan side chains. As in Saccharomyces cerevisiae, chitin was linked via a beta-1,4 linkage to beta-1,3-glucan. The data obtained suggested that the branching of beta-1,3-glucan is an early event in the construction of the cell wall, resulting in an increase of potential acceptor sites for chitin, galactomannan, and the linear beta-1,3/1,4-glucan.     

Cloning of the Candida albicans homolog of Saccharomyces cerevisiae GSC1/FKS1 and its involvement in beta-1,3-glucan synthesis.

Saccharomyces cerevisiae GSC1 (also called FKS1) and GSC2 (also called FKS2) have been identified as the genes for putative catalytic subunits of beta-1,3-glucan synthase. We have cloned three Candida albicans genes, GSC1, GSL1, and GSL2, that have significant sequence homologies with S. cerevisiae GSC1/FKS1, GSC2/FKS2, and the recently identified FKSA of Aspergillus nidulans at both nucleotide and amino acid levels. Like S. cerevisiae Gsc/Fks proteins, none of the predicted products of C. albicans GSC1, GSL1, or GSL2 displayed obvious signal sequences at their N-terminal ends, but each product possessed 10 to 16 potential transmembrane helices with a relatively long cytoplasmic domain in the middle of the protein. Northern blotting demonstrated that C. albicans GSC1 and GSL1 but not GSL2 mRNAs were expressed in the growing yeast-phase cells. Three copies of GSC1 were found in the diploid genome of C. albicans CAI4. Although we could not establish the null mutation of C. albicans GSC1, disruption of two of the three GSC1 alleles decreased both GSC1 mRNA and cell wall beta-glucan levels by about 50%. The purified C. albicans beta-1,3-glucan synthase was a 210-kDa protein as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and all sequences determined with peptides obtained by lysyl endopeptidase digestion of the 210-kDa protein were found in the deduced amino acid sequence of C. albicans Gsc1p. Furthermore, the monoclonal antibody raised against the purified beta-1,3-glucan synthase specifically reacted with the 210-kDa protein and could immunoprecipitate beta-1,3-glucan synthase activity. These results demonstrate that C. albicans GSC1 is the gene for a subunit of beta-1,3-glucan synthase.     

Cloning of the RHO1 gene from Candida albicans and its regulation of beta-1,3-glucan synthesis.

The Saccharomyces cerevisiae RHO1 gene encodes a low-molecular-weight GTPase. One of its recently identified functions is the regulation of beta-1,3-glucan synthase, which synthesizes the main component of the fungal cell wall (J. Drgonova et al., Science 272:277-279, 1996; T. Mazur and W. Baginsky, J. Biol. Chem. 271:14604-14609, 1996; and H. Qadota et al., Science 272:279-281, 1996). From the opportunistic pathogenic fungus Candida albicans, we cloned the RHO1 gene by the PCR and cross-hybridization methods. Sequence analysis revealed that the Candida RHO1 gene has a 597-nucleotide region which encodes a putative 22.0-kDa peptide. The deduced amino acid sequence predicts that Candida albicans Rho1p is 82.9% identical to Saccharomyces Rho1p and contains all the domains conserved among Rho-type GTPases from other organisms. The Candida albicans RHO1 gene could rescue a S. cerevisiae strain containing a rho1 deletion. Furthermore, recombinant Candida albicans Rho1p could reactivate the beta-1,3-glucan synthesis activities of both C. albicans and S. cerevisiae membranes in which endogenous Rho1p had been depleted by Tergitol NP-40-NaCl treatment. Candida albicans Rho1p was copurified with the beta-1,3-glucan synthase putative catalytic subunit, Candida albicans Gsc1p, by product entrapment. Candida albicans Rho1p was shown to interact directly with Candida albicans Gsc1p in a ligand overlay assay and a cross-linking study. These results indicate that Candida albicans Rho1p acts in the same manner as Saccharomyces cerevisiae Rho1p to regulate beta-1,3-glucan synthesis.     

The site of cellulose synthesis. Hormone treatment alters the intracellular location of alkali-insoluble beta-1,4-glucan (cellulose) synthetase activities

Membrane preparations from growing regions of 8-day old Pisum sativum epicotyls contain multiple beta-1,4-glucan (cellulose) synthetase activities (UDP- or GDP-glucose: beta-1,4-glucan-glucosyl transferase), and the levels of some of these are influenced by treatments with the growth hormone, indoleacetic acid (IAA). When membranes from control epicotyl segments (zero time) are fractionated by isopycnic sedimentation in sucrose density gradients, all of the synthetase activities are associated mainly with Golgi membrane (density 1.55 g/cm3). After decapitation and treatment of epicotyls with IAA, synthetases also appear in a smooth vesicle fraction (density 1.11 g/cm3) which is rich in endoplasmic reticulum (ER) marker enzyme. Major fractions of these synthetases are not recovered in association with plasma membrane or washed cell walls. When [14-C]sucrose is supplied in vivo to segments +/- IAA, radioactive cellulose is deposited only in the wall. Cellulose or cellodextrin precursors do not accumulate in those membranes in which synthetase activities are recovered in vitro. In experiments where tissue slices containing intact cells are supplied with [14C]sugar nucleotide in vitro, alkali-insoluble beta-1,4-glucan is synthesized (presumably outside the protoplast) at rates which greatly exceeded (20-30 times) those obtained using isolated membrane preparations. Progressive disruption of cell structure results in increasing losses of this high activity. These results are consistent with the interpretation that Golgi and ER-associated synthetases are not themselves loci for cellulose synthesis in vivo, but represent enzymes in transit to sites of action at the wall:protoplast omterface. There they operate only if integrity of cellular organization is maintained.     

Evidence for a glycosidic linkage between chitin and glucan in the cell wall of Candida albicans

The alkali-insoluble glucan was isolated from regenerating spheroplasts and intact cells of Candida albicans. Sequential enzymic hydrolysis of this fraction by Zymolyase 100T and purified chitinase and subsequent gel filtration produced a fraction which was enriched in glycosaminoglycans. This fraction was analysed by partial acid hydrolysis, TLC and GLC-MS. The GLC-MS peaks identified included 2,3,4,6-tetra-O-methylglucitol acetate and 2,3,4-tri-O-methylglucitol acetate of beta-1,6-glucan and the 3,6-di-O-methyl-2-N-methylglucosaminitol acetate of chitin. In addition, 3-O-methyl-2-N-methylglucosaminitol acetate was identified, which indicated a branch point in chitin. These data provide evidence for a covalent linkage between chitin and beta-(1,6)-glucan through a glycosidic linkage at position 6 of N-acetylglucosamine and position 1 of the glucose in the glucan.     

Covalent association of beta-1,3-glucan with beta-1,6-glucosylated mannoproteins in cell walls of Candida albicans.

Yeast and hyphal walls of Candida albicans were extracted with sodium dodecyl sulfate (SDS). Some of the extracted proteins reacted with a specific beta-1,6-glucan antiserum but not with a beta-1,3-glucan antiserum. They lost their beta-1,6-glucan epitope after treatment with ice-cold aqueous hydrofluoric acid, suggesting that beta-1,6-glucan was linked to the protein through a phosphodiester bridge. When yeast and hyphal walls extracted with SDS were subsequently extracted with a pure beta-1,3-glucanase, several mannoproteins that were recognized by both the beta-1,6-glucan antiserum and the beta-1,3-glucan antiserum were released. Both epitopes were sensitive to aqueous hydrofluoric acid treatment, suggesting that beta-1,3-glucan and beta-1,6-glucan are linked to proteins by phosphodiester linkages. The possible role of beta-glucans in the retention of cell wall proteins is discussed.     

Purification and characterization of a beta-1,3-glucan binding protein from plasma of the crayfish Pacifastacus leniusculus

The plasma of the crayfish Pacifastacus leniusculus contains a protein which is able to bind to laminarin (a soluble beta-1,3-glucan) and which has been isolated by two independent methods, affinity precipitation with a beta-1,3-glucan or immunoaffinity chromatography. The purified beta-1,3-glucan binding protein was homogenous as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. It is a monomeric glycoprotein with a molecular mass of approximately 100,000 Da and an isoelectric point of approximately 5.0. Amino acid analysis showed a very high similarity with the amino acid composition of beta-1,3-glucan binding proteins recently purified from two insects, the cockroach Blaberus craniifer and the silkworm Bombyx mori. The N-terminal amino acid sequence was determined to be: H2N-Asp-Ala-Gly-X-Ala-Ser-Leu-Val-Thr-Asn-Phe-Asn-Ser-Ala-Lys-Leu-X-X-Ly s--- Using monospecific rabbit polyclonal antibodies, the presence of this protein has also been shown within the blood cells. The purified beta-1,3-glucan binding protein did not show any peptidase or phenoloxidase activity but was able to enhance the activation of hemocyte-derived peptidase and prophenoloxidase only in the presence of the beta-1,3-glucan, laminarin, whereas mannan, dextran (alpha-glucan), or cellulose (beta-1,4-glucan) incubated with the beta-1,3-glucan binding protein had no effect on these enzyme activities. The beta-1,3-glucan binding protein could only be affinity-precipitated from crayfish plasma by the beta-1,3-glucans laminarin or curdlan (an insoluble beta-1,3-glucan), while mannan or dextran did not bind to the beta-1,3-glucan binding protein. No hemagglutinating activity of the purified beta-1,3-glucan binding protein could be detected.     

Structural and functional definition of the human chitinase chitin-binding domain

Mammalian chitinase, a chitinolytic enzyme expressed by macrophages, has been detected in atherosclerotic plaques and is elevated in blood and tissues of guinea pigs infected with Aspergillus. Its normal physiological function is unknown. To understand how the enzyme interacts with its substrate, we have characterized the chitin-binding domain. The C-terminal 49 amino acids make up the minimal sequence required for chitin binding activity. The absence of this domain does not affect the ability of the enzyme to hydrolyze the soluble substrate, triacetylchitotriose, but abolishes hydrolysis of insoluble chitin. Within the minimal chitin-binding domain are six cysteines; mutation of any one of these to serine results in complete loss of chitin binding activity. Analysis of purified recombinant chitin-binding domain revealed the presence of three disulfide linkages. The recombinant domain binds specifically to chitin but does not bind chitosan, cellulose, xylan, beta-1, 3-glucan, beta-1,3-1,4-glucan, or mannan. Fluorescently tagged chitin-binding domain was used to demonstrate chitin-specific binding to Saccharomyces cerevisiae, Candida albicans, Mucor rouxii, and Neurospora crassa. These experiments define structural features of the minimal domain of human chitinase required for both specifically binding to and hydrolyzing insoluble chitin and demonstrate relevant binding within the context of the fungal cell wall.     

KRE5 gene null mutant strains of Candida albicans are avirulent and have altered cell wall composition and hypha formation properties

The UDP-glucose:glycoprotein glucosyltransferase (UGGT) is an endoplasmic reticulum sensor for quality control of glycoprotein folding. Saccharomyces cerevisiae is the only eukaryotic organism so far described lacking UGGT-mediated transient reglucosylation of N-linked oligosaccharides. The only gene in S. cerevisiae with similarity to those encoding UGGTs is KRE5. S. cerevisiae KRE5 deletion strains show severely reduced levels of cell wall beta-1,6-glucan polymer, aberrant morphology, and extremely compromised growth or lethality, depending on the strain background. Deletion of both alleles of the Candida albicans KRE5 gene gives rise to viable cells that are larger than those of the wild type (WT), tend to aggregate, have enlarged vacuoles, and show major cell wall defects. C. albicans kre5/kre5 mutants have significantly reduced levels of beta-1,6-glucan and more chitin and beta-1,3-glucan and less mannoprotein than the WT. The remaining beta-1,6-glucan, about 20% of WT levels, exhibits a beta-1,6-endoglucanase digestion pattern, including a branch point-to-linear stretch ratio identical to that of WT strains, suggesting that Kre5p is not a beta-1,6-glucan synthase. C. albicans KRE5 is a functional homologue of S. cerevisiae KRE5; it partially complements both the growth defect and reduced cell wall beta-1,6-glucan content of S. cerevisiae kre5 viable mutants. C. albicans kre5/kre5 homozygous mutant strains are unable to form hyphae in several solid and liquid media, even in the presence of serum, a potent inducer of the dimorphic transition. Surprisingly the mutants do form hyphae in the presence of N-acetylglucosamine. Finally, C. albicans KRE5 homozygous mutant strains exhibit a 50% reduction in adhesion to human epithelial cells and are completely avirulent in a mouse model of systemic infection.     

Phagocytosis by human neutrophils is stimulated by a unique fungal cell wall component

Innate immunity depends upon recognition of surface features common to broad groups of pathogens. The glucose polymer beta-glucan has been implicated in fungal immune recognition. Fungal walls have two kinds of beta-glucan: beta-1,3-glucan and beta-1,6-glucan. Predominance of beta-1,3-glucan has led to the presumption that it is the key immunological determinant for neutrophils. Examining various beta-glucans for their ability to stimulate human neutrophils, we find that the minor cell wall component beta-1,6-glucan mediates neutrophil activity more efficiently than beta-1,3-glucan, as measured by engulfment, production of reactive oxygen species, and expression of heat shock proteins. Neutrophils rapidly ingest beads coated with beta-1,6-glucan while ignoring those coated with beta-1,3-glucan. Complement factors C3b/C3d are deposited on beta-1,6-glucan more readily than on beta-1,3-glucan. Beta-1,6-glucan is also important for efficient engulfment of the human pathogen Candida albicans. These unique stimulatory effects offer potential for directed stimulation of neutrophils in a therapeutic context.     

The structure of a β-(1→3)-d-glucan from yeast cell walls

Yeast glucan as normally prepared by various treatments of yeast (Saccharomyces cerevisiae) cell walls to remove mannan and glycogen is still heterogeneous. The major component (about 85%) is a branched beta-(1-->3)-glucan of high molecular weight (about 240000) containing 3% of beta-(1-->6)-glucosidic interchain linkages. The minor component is a branched beta-(1-->6)-glucan. A comparison of our results with those of other workers suggests that different glucan preparations may differ in the degree of heterogeneity and that the major beta-(1-->3)-glucan component may vary considerably in degree of branching.     

A protein-glucan intermediate during paramylon synthesis.

A sodium deoxycholate extract containing glucosyltransferase activity was obtained from a particulate preparation from Euglena gracilis. It transferred glucose from UDP-[14C]glucose into material that was precipitated by trichloroacetic acid. This material released beta-(1 leads to 3)-glucan oligosaccharides into solution on incubation with weak acid, weak alkali and beta-(1 leads to 3)-glucosidase. The products of the incubation of the deoxycholate extract with UDP-[14C]glucose were analysed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Radioactive bands were obtained that had the properties of beta-(1 leads to 3)-glucan covalently linked to protein by a bond labile to weak acid. High-molecular-weight material containing a beta-(1 leads to 3)-glucan was also shown to be present by gel filtration. The bond linking glucan to aglycone is possibly a pyrophosphate linkage. It is proposed that in Euglena gracilis beta-(1 leads to 3)-glucan (paramylon) is synthesized on a protein primer.     

The cell wall of Fusarium oxysporum.

Sugar analysis of isolated cell walls from three formae speciales of Fusarium oxysporum showed that they contained not only glucose and (N-acetyl)-glucosamine, but also mannose, galactose, and uronic acids, presumably originating from cell wall glycoproteins. Cell wall glycoproteins accounted for 50-60% of the total mass of the wall. X-ray diffraction studies showed the presence of alpha-1, 3-glucan in the alkali-soluble cell wall fraction and of beta-1, 3-glucan and chitin in the alkali-insoluble fraction. Electron microscopy and lectin binding studies indicated that glycoproteins form an external layer covering an inner layer composed of chitin and glucan.     

In vitro synthesis of a microfibrillar (1→3)-β-glucan by a ryegrass (Lolium multiflorum) endosperm (1→3)-β-glucan synthase enriched by product entrapment

A simple, rapid procedure has been developed to purify (1→3)-β-glucan synthase (UDP-Glc:(1→3)-β-glucan 3-β-d -glucosyl transferase (EC 2.4.1.34)) over 400-fold from membrane preparations of Italian ryegrass (Lolium multiflorum) and 60-fold from CHAPS-extracted membranes. When a CHAPS-extract of the membranes is treated with 8 mM CaCl₂, proteinaceous material is precipitated. Although less than 10% of CHAPS-solubilized protein is removed in this step, the total activity recovered in the supernatant increases fourfold. Thus, CaCl₂ precipitation appears to be important in removing inhibitors of the (1→3)-β-glucan synthase. In the presence of 1 mM UDP-glucose, the supernatant after CaCl₂ treatment produces a high molecular weight, insoluble product that entraps a (1→3)-β-glucan synthase of high specific activity. The product-entrapped enzyme preparation contains six major polypeptides, and comparison of the SDS—PAGE pattern of this fraction with the polypeptide profile of an immunoprecipitated (1→3)-β-glucan synthase preparation suggests that polypeptides at 30–31 and 55–58 kDa are the most likely candidates for participation in (1→3)-β-glucan synthesis. When the reaction is performed on a larger scale, milligram quantities of product can be seen precipitating from the reaction mixture within 1 h of substrate addition. This product has been characterized by methylation analysis, ¹H- and ¹³C-nmr spectroscopy, X-ray diffraction, electron microscopy, size exclusion chromatography, UV-induced fluorescence in the presence of the (1→3)-β-glucan-specific fluorochrome from aniline blue, and enzymic hydrolysis with a specific (1→3)-β-glucanase. These physical, chemical and enzymic analyses clearly demonstrate that the product is a microfibrillar (1→3)-β-glucan with a degree of polymerization of about 1500.     

A refined method for the determination of Saccharomyces cerevisiae cell wall composition and beta-1,6-glucan fine structure.

In yeast and other fungi, cell division, cell shape, and growth depend on the coordinated synthesis and degradation of cell wall polymers. We have developed a reliable and efficient micro method to determine Saccharomyces cerevisiae cell wall composition that distinguishes between beta1,3- and beta1,6-glucan. The method is based on the sequential treatment of cell walls with specific hydrolytic enzymes followed by dialysis. The low molecular weight (MW) products thus separated account for each particular cell wall polymer. The method can be applied to as little as 50-100 mg (wet wt) of radioactively labeled cells. A combination of chitinase and recombinant beta-1,3-glucanase is initially used, releasing all of the chitin and 60-65% of the beta1,3-glucan from the cell walls. Next, recombinant endo-beta-1,6-glucanase from Trichoderma harzianum is utilized to release all the beta-1,6-glucan present in the wall. The chromatographic pattern of endoglucanase digested beta-1,6-glucan provides a characteristic "fingerprint" of beta-1,6-glucan and the fine structure of the oligosaccharides in this pattern was determined by 1H NMR and electrospray ionization mass spectroscopy. The final enzymatic step uses laminarinase and beta-glucosidase to release the remaining beta-1,3-glucan. The cell wall mannan remains as a high MW fraction at the end of the fractionation procedure. Good sensitivity and correlation with cell wall composition determined by traditional methods were observed for wild-type and several cell wall mutants.     

The cell wall architecture of Candida albicans wild-type cells and cell wall-defective mutants

In Candida albicans wild-type cells, the beta1, 6-glucanase-extractable glycosylphosphatidylinositol (GPI)-dependent cell wall proteins (CWPs) account for about 88% of all covalently linked CWPs. Approximately 90% of these GPI-CWPs, including Als1p and Als3p, are attached via beta1,6-glucan to beta1,3-glucan. The remaining GPI-CWPs are linked through beta1,6-glucan to chitin. The beta1,6-glucanase-resistant protein fraction is small and consists of Pir-related CWPs, which are attached to beta1,3-glucan through an alkali-labile linkage. Immunogold labelling and Western analysis, using an antiserum directed against Saccharomyces cerevisiae Pir2p/Hsp150, point to the localization of at least two differentially expressed Pir2 homologues in the cell wall of C. albicans. In mnn9Delta and pmt1Delta mutant strains, which are defective in N- and O-glycosylation of proteins respectively, we observed enhanced chitin levels together with an increased coupling of GPI-CWPs through beta1,6-glucan to chitin. In these cells, the level of Pir-CWPs was slightly upregulated. A slightly increased incorporation of Pir proteins was also observed in a beta1, 6-glucan-deficient hemizygous kre6Delta mutant. Taken together, these observations show that C. albicans follows the same basic rules as S. cerevisiae in constructing a cell wall and indicate that a cell wall salvage mechanism is activated when Candida cells are confronted with cell wall weakening.     

Differential behaviour of four plant polysaccharide synthases in the presence of organic solvents.

The behaviour of four membrane-bound glycosyl transferases involved in cell wall polysaccharide synthesis has been studied in relation to the effects of a graded series of organic solvents on their activity and type of product formed. Relative enzyme inhibition observed for some solvents was in direct relationship to the hydrophilicity of the product. This was in the order of arabinan synthase > callose synthase> xylan synthase > beta-1,4-glucan synthase. The former two were always inhibited, the xylan synthase rather less so. However, the beta-1,4-glucan synthase showed significant increases in substrate incorporation in the presence of solvents. A graded series of primary alcohols were much more effective in enhancing activity than acetone, ethyl acetate and dimethyl formamide. In the presence of the most effective solvent, methanol, there was considerable activation of beta-1,4-glucan production. This reciprocal nature of the behaviour of the beta-1,4- and beta-1,3-glucan synthases in organic solvent is supportive of recent molecular data that the two types of glucans are catalysed by separate enzyme systems. However, the results reported here do not totally negate the proposition that either enzyme is capable of synthesising the other linkage in minor amounts in vitro.     

Structural analysis of the lipopolysaccharide from nontypeable Haemophilus influenzae strain R2846

We here report the lipopolysaccharide (LPS) structures expressed by nontypeable Haemophilus influenzae R2846, a strain whose complete genome sequence has recently been obtained. Results were obtained by using NMR techniques and ESI-MS on O-deacylated LPS and core oligosaccharide material (OS) as well as ESI-MS (n) on permethylated dephosphorylated OS. A beta- d-Glc p-(1-->4)- d-alpha- d-Hep p-(1-->6)-beta- d-Glc p-(1-->4) unit was found linked to the proximal heptose (HepI) of the conserved triheptosyl inner-core moiety, l-alpha- d-Hep p-(1-->2)-[ PEtn-->6]- l-alpha- d-Hep p-(1-->3)- l-alpha- d-Hep p-(1-->5)-[ PPEtn-->4]-alpha-Kdo-(2-->6)-lipid A. The beta- d-Glc p (GlcI) linked to HepI was also branched with oligosaccharide extensions from O-4 and O-6. O-4 of GlcI was substituted with sialyllacto- N-neotetraose [alpha-Neu5Ac-(2-->3)-beta- d-Gal p-(1-->4)-beta- d-Glc pNAc-(1-->3)-beta- d-Gal p-(1-->4)-beta- d-Glc p-(1-->] and the related structure [( PEtn-->6)-alpha- d-Gal pNAc-(1-->6)-beta- d-Gal p-(1-->4)-beta- d-Glc pNAc-(1-->3)-beta- d-Gal p-(1-->4)-beta- d-Glc p-(1-->]. The distal heptose (HepIII) was substituted at O-2 by beta- d-Gal. Phosphate, phosphoethanolamine, phosphocholine, acetate, and glycine were found to substitute the core oligosaccharide. Two heptosyltransferase genes, losB1 and losB2, have been identified from the R2846 genome sequence and are candidates to add the noncore heptose to the LPS. Mutant strain R2846 losB1 did not show dd-heptose in the extension from HepI but still contained minor quantities of ld-heptose at the same position, indicating that the losB1 gene is required to add dd-heptose to GlcI. The LPS from strain R2846 losB1/ losB2 expressed no noncore heptose, consistent with losB2 directing the addition of ld-heptose.     

Enzymic hydrolysis of barley and other β-glucans by a β-(1→4)-glucan hydrolase

1. A barley glucan with 68% of beta-(1-->4)-linkages and 32% of beta-(1-->3)-linkages was exhaustively hydrolysed with an Aspergillus niger beta-(1-->4)-glucan 4-glucanohydrolase (EC 3.2.1.4) (Clarke & Stone, 1965b). The hydrolysis products were separated and estimated. 2. The lower-molecular-weight products were identified as: glucose, 1.4%; cellobiose, 11.9%; 3(2)-O-beta-glucosylcellobiose, 45.0%; a tetrasaccharide(s), which was a substituted cellobiose, 16.4%. A series of unidentified higher-molecular-weight products (26.5%) were also found. 3. The identity of the products suggests that the A. niger beta-(1-->4)-glucan hydrolase hydrolyses beta-glucosidic linkages joining 4-O-substituted glucose residues. 4. When an enzyme fraction containing the beta-(1-->4)-glucan hydrolase and an exo-beta-(1-->3)-glucan hydrolase was used, the same products were found, but the higher-molecular-weight products were observed to have only a transient existence in the hydrolysate and were virtually absent after prolonged incubation. It is suggested that these oligosaccharides are resistant to attack by beta-(1-->4)-glucan hydrolase but are partially hydrolysed by the exo-beta-(1-->3)-glucan hydrolase and therefore possess one or more (1-->3)-linked glucose residues at their non-reducing end.