V. S. Kumar Kolli

The structures of arabinoxyloglucans produced by solanaceous plants

Several structural features, most notably the presence of alpha-L-Araf-(1-->2)-alpha-D-Xylp side chains, distinguish the arabinoxyloglucans (AXGs) produced by solanaceous plants from the xyloglucans produced by other dicotyledonous plants. However, previous studies did not establish the exact order of attachment of the various side chains along the backbone of these AXGs. Therefore, oligosaccharide subunits of the AXGs secreted by suspension-cultured tobacco and tomato cells were generated by treatment of the isolated AXGs with a fungal endo-beta-(1-->4)-D-glucanase (EG). The oligosaccharides were reduced with sodium borohydride to the corresponding oligoglycosyl alditol derivatives and purified by a combination of gel-permeation chromatography, reversed-phase HPLC, and HPAE chromatography. The isolated oligoglycosyl alditols were chemically characterized by NMR spectroscopy, matrix-assisted laser-desorption/ionization time-of-flight mass spectrometry (MALDITOFMS), fast-atom bombardment mass spectrometry (FABMS), FABMS/MS, and glycosyl-linkage analysis. The results confirmed that the AXGs from these species are composed of a (1-->4)-linked beta-D-Glcp backbone substituted at O-6 with various side chains. Both tobacco and tomato AXG contain alpha-D-Xylp and alpha-L-Araf-(1-->2)-alpha-D-Xylp side chains. However, oligosaccharide fragments of tomato AXG were also shown to contain beta-D-Galp-(1-->2)-alpha-D-Xylp and beta-Araf-(1-->3)-alpha-L-Araf-(1-->2)-alpha-D-Xylp side chains that are not present in the tobacco AXG. This is the first report of beta-Araf residues in a xyloglucan. The primary structures of 20 oligosaccharides generated by EG-treatment of tobacco AXG were determined. The generation of such a large number of oligosaccharides is due in part to the presence of O-acetyl substituents at O-6 of many of the backbone beta-D-Glcp residues of tobacco AXG. The presence of either an O-acetyl or a glycosidic substituent at O-6 of a beta-D-Glc p residue in the AXG backbone protects the glycosidic bond of this residue from cleavage by the EG. Removal of the O-acetyl substituents prior to EG-treatment of the AXG-results in oligosacharide fragments that are smaller than those produced by EG-treatment of the O-acetylated AXG. Therefore, analysis of the complex mixture of oligosaccharides obtained by EG treatment of native tobacco AXGs provides information regarding the distribution of AXG side chains that would be lost if the AXG is de-O-acetylated prior to EG-treatment. Furthermore, the large library of oligosaccharide fragments generated by this approach revealed additional correlations between the structural features of AXGs and diagnosis chemical shift effects in their 1H NMR spectra.

Endotoxin of Neisseria meningitidis composed only of intact lipid A: Inactivation of the meningococcal 3-deoxy-D-manno-octulosonic acid transferase

Lipopolysaccharide, lipooligosaccharide (LOS), or endotoxin is important in bacterial survival and the pathogenesis of gram-negative bacteria. A necessary step in endotoxin biosynthesis is 3-deoxy-D-manno-octulosonic acid (Kdo) glycosylation of lipid A, catalyzed by the Kdo transferase KdtA (WaaA). In enteric gram-negative bacteria, this step is essential for survival. A nonpolar kdtA::aphA-3 mutation was created in Neisseria meningitidis via allelic exchange, and the mutant was viable. Detailed structural analysis demonstrated that the endotoxin of the kdtA::aphA-3 mutant was composed of fully acylated lipid A with variable phosphorylation but without Kdo glycosylation. In contrast to what happens in other gram-negative bacteria, tetra-acylated lipid IV(A) did not accumulate. The LOS structure of the kdtA::aphA-3 mutant was restored to the wild-type structure by complementation with kdtA from N. meningitidis or Escherichia coli. The expression of a fully acylated, unglycosylated lipid A indicates that lipid A biosynthesis in N. meningitidis can proceed without the addition of Kdo and that KdtA is not essential for survival of the meningococcus.

Cooperative action of lipo-chitin nodulation signals on the induction of the early nodulin, ENOD2, in soybean roots

Various lipo-chitin molecules were tested for their ability to induce the expression of the early nodulin, ENOD2, in Glycine soja roots. When inoculated separately onto G. soja roots, LCO-V (C18:1 delta 11,Mefuc), LCO-V (C18:1 delta 9,Mefuc), LCO-V (C16:0,Mefuc), and LCO-IV (C16:0) were unable to induce ENOD2 expression, even though these compounds had previously been shown to induce root hair curling, the formation of nodule-like primordia, and induction of the early nodulin, ENOD40. ENOD2 expression, however, was induced when any two of these molecules were inoculated in combination. Thus, the lipo-chitin nodulation signals appear to act cooperatively to induce ENOD2 expression. B. japonicum strains USDA110 and USDA135 and B. elkanii strain USDA61, all symbionts of soybean, were found to produce at least two distinct nod signals ([i.e., NodBj-V[C18:1,Mefuc] and NodBj-V[C16:0,Mefuc]). These two compounds were mixed in various ratios and tested for their ability to induce ENOD2 expression. The results indicate that the former compound must be present in equivalent or excess amount in order to obtain maximum ENOD2 expression. Additional nonspecific LCOs (e.g., LCO-IV[C16:2 delta 2,9; SO3]), incapable of inducing root hair curling or cortical cell division, were tested in combination with the four active LCOs listed above. It was found that any combination of one active LCO with a nonspecific LCO was sufficient to induce ENOD2 mRNA expression. The ENOD2 mRNA expression pattern detected by in situ hybridization closely resembled that found in bacterial-induced nodules with expression detected in cortical cells between primary and secondary meristems and around the vascular strands. These data demonstrate that the cooperative action of at least two LCO nodulation signals leads to a greater progression of nodule ontogeny as demonstrated by the expression of ENOD2, a marker gene for the differentiation of nodule parenchyma.

Structural analyses of two arabinose containing oligosaccharides derived from olive fruit xyloglucan: XXSG and XLSG.

Xyloglucan oligosaccharides were prepared by endo-(1-->4)-beta-D-glucanase digestion of alkali-extractable xyloglucan from olive fruit and purified by a combination of gel-permeation (Bio-Gel P-2) chromatography and high-performance anion-exchange chromatography. The two most abundant oligosaccharides were converted to the corresponding oligoglycosyl alditols by borohydride reduction and structurally characterised by NMR spectroscopy and post-source decay (PSD) fragment analysis of matrix-assisted laserinduced desorption/ionisation time-of-flight (MALDI-TOF) mass spectra. The results revealed that olive fruit xyloglucan is mainly built from two novel oligosaccharides: XXSG and XLSG. The structure of the oligosaccharides confirmed the presence of a specific xyloglucan in olive fruit with alpha-L-Araf-(1-->2)-alpha-D-Xylp sidechains as was suggested previously. The presence of such sidechains is a common feature of xyloglucans with an XXGG core produced by solanaceous plants but has not been demonstrated for other dicotyledonous plants, which have in general an XXXG core. Direct treatment of cell wall material from olive fruit with pectin degrading enzymes in combination with endo-(1-->4)-beta-D-glucanase revealed that some of the arabinose residues of the oligosaccharides XXSG and XLSG are substituted with either 1 or 2 O-acetyl groups.

All-or-none N-glycosylation in primate follicle-stimulating hormone β-subunits

Abstract Human FSH exists as two major glycoforms designated, tetra-glycosylated and di-glycosylated hFSH. The former possesses both α- and β-subunit carbohydrates while the latter possesses only α-subunit carbohydrate. Western blotting differentiated the glycosylated, 24,000 M r hFSHβ band from the non-glycosylated 21,000 M r FSHβ band. Postmenopausal urinary hFSH preparations possessed 75–95% 24,000 M r hFSHβ, while pituitary hFSH immunopurified from 21- to 43-year-old females and 21–43-year-old males possessed only 35–40% 24,000 M r hFSHβ. The pituitary hFSH from a postmenopausal woman on estrogen replacement was 75% 21,000 M r hFSHβ. Other immunopurified postmenopausal pituitary hFSH preparations possessed 50–60% 21,000 M r hFSHβ. Gel filtration removed predominantly 21,000 M r free hFSHβ and reduced its abundance to 13–22% in postmenopausal pituitary hFSH heterodimer preparations. A major regulatory mechanism for FSH glycosylation involves control of β-subunit N -glycosylation, possibly by inhibition of oligosaccharyl transferase. Two primate species exhibited the same all-or-none pattern of pituitary FSHβ glycosylation.

A New Matrix for Matrix-assisted Laser Desorption/Ionization on Magnetic Sector Instruments with Point Detectors

A new matrix consisting of a binary mixture of alpha-cyano-4-hydroxycinnamic acid and 3-amino-quinoline has been developed specifically for matrix-assisted laser desorption/ionization (MALDI) analysis on magnetic sector mass spectrometers with point detectors. The major benefit of this matrix is that it is a viscous liquid with a self-healing surface. These properties provide very long-lasting and reasonably constant ion currents from pmol quantities of analyte, allowing MALDI-magnetic sector spectra to be obtained even though a non-integrating point detector is used. The applicability of this matrix for biological samples is demonstrated by analyzing a mixture of complex N-linked oligosaccharides with the new liquid matrix and with several traditional solid MALDI matrices both on magnetic sector and time-of-flight instruments.

The membrane phospholipids of Neisseria meningitidis and Neisseria gonorrhoeae as characterized by fast atom bombardment mass spectrometry.

The phospholipids of Neisseria meningitidis and Neisseria gonorrhoeae were characterized by fast atom bombardment (FAB)-MS and GLC-MS. The major phospholipids were phosphatidylethanolamine (PE), followed by phosphatidylglycerol (PG), with minor amounts of phosphatidic acid (PA) and trace levels of cardiolipin (DPG). All of the phospholipid preparations were variable in their fatty acyl substituents, which included C16:1, C16:0, C18:1, C14:0, C14:1 and C12:0. By MS/MS analysis, all pathogenic Neisseria spp. phospholipids contained a saturated fatty acyl substituent and either a saturated or unsaturated fatty acyl substituent in the sn-1 and sn-2 positions, respectively. Compared with enteric bacterial species, the phospholipids of N. meningitidis and N. gonorrhoeae have increased levels of phospholipids with short-chain fatty acyl residues (i.e. increases in C12:0, C14:1 and C14:0) and variable amounts of C18:1. The percentage of total PE and PG molecules with the shorter-chain fatty acids ranges from 35 to 47% and 42 to 66%, respectively, for N. meningitidis while these respective values are <10% and <5% for Escherichia coli. The variability and variety of meningococcal and gonococcal phospholipids suggest novel genetic mechanisms of neisserial phospholipid assembly and regulation, which may be important for the biology and pathogenesis of N. meningitidis and N. gonorrhoeae.

Phase variable changes in genes lgtA and lgtC within the lgtABCDE operon of Neisseria gonorrhoeae can modulate gonococcal susceptibility to normal human serum

The α-chain of the core oligosaccharide of the lipo-oligosaccharide (LOS) produced by Neisseria gonorrhoeae can undergo reversible and rapid changes in structure due to phase-variable production of certain enzymes employed in the biosynthesis of the lacto-N-neotetraose structure. Five of these enzymes are encoded by the lgtABCDE operon, and polynucleotide tracts within three of these genes (lgtA, lgtC and lgtD) can be substrates for slipped-strand mispairing events that lead to nucleotide insertions or deletion events which result in variable production of their respective gene products. We now report that phase-variable synthesis of the lgtA and lgtC gene products in strain FA19 results in the production of elongated LOS α-chains and that the presence of these LOS species can result in gonococci being sensitive to the bacteriolytic action of serum-antibody and complement. Hence, phase variation within the lgtABCDE operon can significantly impact the ability of gonococci to subvert this important host defense system.

Characterization of a novel lipid-A from Rhizobium species Sin-1. A unique lipid-A structure that is devoid of phosphate and has a glycosyl backbone consisting of glucosamine and 2-aminogluconic acid.

The structure of the lipid-A fromRhizobium species Sin-1, a nitrogen-fixing Gram-negative bacterial symbiont of Sesbania, was determined by composition, nuclear magnetic resonance spectroscopic, and mass spectrometric analyses. The lipid-A preparation consisted of a mixture of structures due to differences in fatty acylation and in the glycosyl backbone. There were two different disaccharide backbones. One disaccharide consisted of a distal glucosaminosyl residue β-linked to position 6 of a proximal 2-aminoglucono-1,5-lactonosyl residue, and in the second disaccharide, the proximal residue was 2-amino-2,3-dideoxy-d-erythro-hex-2-enono-1,5-lactone. For both disaccharides, the distal glucosamine was acylated at C-2′ primarily with β-hydroxypalmitate (β-OHC16:0) which, in turn, was O-acylated with 27-hydroxyoctacosanoic acid. For some of the lipid-A molecules, the distal glucosaminosyl residue was also acylated at C-3′ with β-hydroxymyristate (β-OHC14:0), whereas other molecules were devoid of this acyl substituent. Both the 2-aminoglucono-1,5-lactonosyl and 2-amino-2,3-dideoxy-d-erythro-hex-2-enono-1,5-lactonosyl residues were acylated at C-2, primarily with β-OHC16:0. Minor amounts of lipid-A molecules contained β-OHC14:0 at C-3 and/or β-hydroxystearate (β-OHC18:0) or β-hydroxyoctadecenoate (β-OHC18:1) as the C-2 and C-2′ N-acyl substituents.

Genetic Locus Required for Antigenic Maturation of Rhizobium etli CE3 Lipopolysaccharide

Rhizobium etli modifies lipopolysaccharide (LPS) structure in response to environmental signals, such as low pH and anthocyanins. These LPS modifications result in the loss of reactivity with certain monoclonal antibodies. The same antibodies fail to recognize previously isolated R. etli mutant strain CE367, even in the absence of such environmental cues. Chemical analysis of the LPS in strain CE367 demonstrated that it lacked the terminal sugar of the wild-type O antigen, 2,3,4-tri-O-methylfucose. A 3-kb stretch of DNA, designated as lpe3, restored wild-type antigenicity when transferred into CE367. From the sequence of this DNA, five open reading frames were postulated. Site-directed mutagenesis and complementation analysis suggested that the genes were organized in at least two transcriptional units, both of which were required for the production of LPS reactive with the diagnostic antibodies. Growth in anthocyanins or at low pH did not alter the specific expression of gusA from the transposon insertion of mutant CE367, nor did the presence of multiple copies of lpe3 situated behind a strong, constitutive promoter prevent epitope changes induced by these environmental cues. Mutations of the lpe genes did not prevent normal nodule development on Phaseolus vulgaris and had very little effect on the occupation of nodules in competition with the wild-type strain.