Tissue-specific developmental changes in cell-wall ferulate and dehydrodiferulates in sugar beet.

Sugar beet (Beta valgaris L.) seedlings were grown for 8-14 weeks, and then separated into leaf, petiole, inner and outer storage root and absorptive root fractions. Cell-wall ferulate and dehydrodiferulate esters were analysed by HPLC. In leaves, ferulate dimers were mostly 8-8 linked, while 8-O-4 and sometimes 8-5 linkages were most abundant in all other tissues. The total dimer content and percentage of dimerisation were much higher in the absorptive root than in other tissues. These results indicated varying patterns of ferulate and dehydrodiferulate ester content in different tissues, suggesting corresponding variations in the biosynthetic processes. When [14C]-cinnamate was applied to the leaves at 4 weeks, and [14C]-dimers measured in root cell walls at 8 and 14 weeks, a much higher proportion of 8-5 linkages was found in the [14C]-dimers than in total (non-radioactive) dimers in all parts of the root, especially at 14 weeks, indicating further complexity in the metabolism of cell-wall phenolics.

Protein- and pH-dependent binding of nascent pectin and glucuronoarabinoxylan to xyloglucan in pea.

Nascent pectin and glucuronoarabinoxylan, synthesised in vitro by membrane-bound enzymes from etiolated pea (Pisum sativum L.) epicotyls, were found to bind to pea xyloglucan in a pH-dependent manner. The binding was maximum at low pH (3-4), and decreased to almost zero at pH 6. The binding was probably non-covalent and reached saturation within 5 min. Removal of the fucose residues of xyloglucan decreased the degree of binding. Removal by protease of the proteins attached to nascent pectin and glucuronoarabinoxylan greatly reduced the maximum binding and abolished the pH-dependence. The observed binding may be of considerable significance in the process of cell-wall assembly and in the control of cell extension.

Cellulose microfibrils in plants: biosynthesis, deposition, and integration into the cell wall.

Cellulose occurs in all higher plants and some algae, fungi, bacteria, and animals. It forms microfibrils containing the crystalline allomorphs, cellulose I alpha and I beta. Cellulose molecules are 500-15,000 glucose units long. What controls molecular size is unknown. Microfibrils are elongated by particle rosettes in the plasma membrane (cellulose synthase complexes). The precursor, UDP-glucose, may be generated from sucrose at the site of synthesis. The biosynthetic mechanism may involve lipid-linked intermediates. Cellulose synthase has been purified from bacteria, but not from plants. In plants, disrupted cellulose synthase may form callose. Cellulose synthase genes have been isolated from bacteria and plants. Cellulose-deficient mutants have been characterised. The deduced amino acid sequence suggests possible catalytic mechanisms. It is not known whether synthesis occurs at the reducing or nonreducing end. Endoglucanase may play a role in synthesis. Nascent cellulose molecules associate by Van der Waals and hydrogen bonds to form microfibrils. Cortical microtubules control microfibril orientation, thus determining the direction of cell growth. Self-assembly mechanisms may operate. Microfibril integration into the wall occurs by interactions with matrix polymers during microfibril formation.

Binding of nascent glucuronoxylan to the cell walls of pea seedlings.

Glucuronoxylan synthesised in vitro by membrane-bound enzymes from etiolated pea epicotyls was found to bind to isolated cell walls from the same tissue in a pH-dependant manner. The binding was maximum at pH 3.5-4.0, and decreased to zero at pH 6. The bound glucuronoxylan could be dissociated from the cell walls by washing at pH 6, and the binding appeared to be non-covalent. Extraction experiments indicated that the glucuronoxylan was binding to hemicellulose in the cell-wall. The observed binding may be significant in the process of cell-wall assembly in vivo.

Interpretation of the emergency electrocardiogram by junior hospital doctors.

OBJECTIVE: To assess the ability of a cohort of junior hospital doctors to interpret ECGs which have immediate clinical relevance and influence subsequent management of patients. METHODS: 57 junior hospital doctors were interviewed and asked to complete a standard questionnaire which included eight ECGs for interpretation and a supplementary question relating to the administration of thrombolytic treatment. Each doctor was assessed over a 48 h period while they performed their daily clinical duties. RESULTS: The major abnormality of anterior myocardial infarction was recognised by almost all doctors. There was difficulty in the interpretation of posterior myocardial infarction and second degree heart block. Most myocardial infarctions would have been given satisfactory thrombolysis, but there was a reluctance to use this treatment in patients with posterior myocardial infarction and left bundle brach block. A few patients without myocardial infarction would have received thrombolytic treatment. CONCLUSIONS: There is varying ability among junior hospital doctors in the interpretation of the emergency electrocardiogram. The results are of concern as poor interpretation of the ECG can result in inappropriate management. As a result of the findings of this study it is proposed to introduce more formal training in the interpretation of clinically relevant ECG abnormalities for junior hospital doctors.

Differential distribution of a glucuronyltransferase, involved in glucuronoxylan synthesis, within the Golgi apparatus of pea (Pisum sativum var. Alaska).

The subcellular location of a glucuronyltransferase (GT) involved in glucuronoxylan synthesis in pea (Pisum sativum) has been investigated. Most of the GT activity was found in the Golgi fraction, but activity was also detected in the plasma-membrane fraction. Separation of Golgi membranes on a shallow continuous sucrose density gradient resulted in three distinct subfractions, with GT activity being confined to Golgi membranes of a density similar to that of smooth endoplasmic reticulum. The differential distribution of GT within the Golgi stack indicates that glucuronoxylan synthesis occurs in specific cisternae and that there is functional compartmentalization of the Golgi with respect to hemicellulose biosynthesis.

The solubilization of a glucuronyltransferase involved in pea (Pisum sativum var. Alaska) glucuronoxylan synthesis.

A glucuronyltransferase involved in glucuronoxylan biosynthesis was obtained from the epicotyls of 1-week-old etiolated pea (Pisum sativum var. Alaska) seedlings and was solubilized in Triton X-100, a non-ionic detergent. The enzyme was inactivated by SDS and inhibited by Derriphat 160 and cholic acid. The enzyme was active in the presence of NN-dimethyldodecylanium-N-oxide, but was not solubilized by it. The stimulatory effect of UDP-D-xylose on the particulate and solubilized enzymes was the same, but the optimum Mn2+ concentration was lower for the solubilized enzyme, and the product formed by the solubilized enzyme has altered structure and solubility properties. Gel filtration of the solubilized enzyme on Sepharose CL-6B permitted partial separation of the stimulatory effect of UDP-D-xylose from the activity in the absence of UDP-D-xylose. The solubilized enzyme was more stable than the particulate enzyme and could be stored for 2 weeks at -20 degrees C without loss of activity.

The interaction of xylosyltransferase and glucuronyltransferase involved in glucuronoxylan synthesis in pea (Pisum sativum) epicotyls.

A particulate enzyme preparation from etiolated pea (Pisum sativum) epicotyls was found to incorporate xylose from UDP-D-xylose into beta-(1----4)-xylan. The ability of this xylan to act as an acceptor for incorporation of [14C]glucuronic acid from UDP-D-[14C]glucuronic acid in a subsequent incubation was very limited, even though glucuronic acid incorporation was greatly prolonged when UDP-D-xylose was present in the same incubation as UDP-D-[14C]glucuronic acid. This indicated that glucuronic acid could not be added to preformed xylan. However, the presence of UDP-D-glucuronic acid inhibited incorporation of [14C]xylose from UDP-D-[14C]xylose into beta-(1----4)-xylan, and neither S-adenosylmethionine nor acetyl-CoA stimulated either the xylosyltransferase or the glucuronyltransferase.

A xylosyltransferase involved in the synthesis of a protein-associated xyloglucan in suspension-cultured dwarf-French-bean (Phaseolus vulgaris) cells and its interaction with a glucosyltransferase.

A particulate enzyme preparation made from suspension-cultured dwarf-French-bean (Phaseolus vulgaris) cv. Canadian Wonder cells was shown to incorporate xylose from UDP-D-[14C]xylose into polysaccharide. The reaction was dependent upon the presence of UDP-D-glucose and was stimulated, and apparently protected, by GDP-D-glucose and GDP-D-mannose, though neither was able to replace UDP-D-glucose as a glycosyl donor. The product of the reaction was identified as xyloglucan by analysis of products of enzyme breakdown and acid hydrolysis. Mr determination after proteinase K digestion indicated that the nascent xyloglucan is closely associated with protein. Preincubation of the enzyme with UDP-D-glucose stimulated incorporation from UDP-D-[14C]xylose, suggesting an 'imprecise' mechanism of biosynthesis, as defined by Waldron & Brett [(1985) in Biochemistry of Plant Cell Walls (Brett, C. T. & Hillman, J. R., eds.) (SEB Semin. Ser. 28), pp. 79-97, Cambridge University Press, Cambridge].

A glucuronyltransferase involved in glucuronoxylan synthesis in pea (Pisum sativum) epicotyls.

A particulate enzyme preparation made from epicotyls of 1-week-old etiolated pea (Pisum sativum) seedlings was shown to incorporate glucuronic acid from UDP-D-[U-14C]glucuronic acid into a hemicellulosic polysaccharide. Optimum conditions for the incorporation include the presence of Mn2+ ions at between 4 and 10 mmol/litre and a pH between 5 and 6. UDP-D-xylose at 1 mmol/litre allows incorporation to continue for at least 8 h. In its absence, the reaction stops within 30 min. Analysis of the product by partial and total acid hydrolysis, followed by paper chromatography or electrophoresis, indicates that the polysaccharide produced is a glucuronoxylan.

Glycoproten biosynthesis in Trypanosoma brucei. The glycosylation of Glycoproteins located in and attached to the plasma membrane.

1. Glycosyltransferase activity incorporating N-[14C]acetylglucosamine ([14C]GlcNAc) from uridine diphosphate N-[14C]acetylglucosamine (UDP-[14C]GlcNAc) into endogenous proitein acceptors was localized primarily in the plasma membrane of Trypanosoma brucei. 2. The acceptor site for the nucleotide sugar was further localized exclusively to the cytoplasmic face of the plasma membrane. 3. The glycosyltransferase produced elongation of the growing oligosaccharide chains while they were attached to their peptide acceptors. 4. This glycosyltransferase activity was incapable of initiating sugar attachment directly to amino acid residues within peptide acceptors. 5. The dolichyl-phosphate-sugar pathway for glycoprotein biosynthesis was either absent of only present at a very low level in T. brucei when compared to rat liver. 6. All oligosaccharide chains accepting GlcNAc were of the same or very similar lengths. 7. Both O-glycosidic (26%) and N-glycosidic (74%) linkages (exclusive of hydroxylysine attachment) were found. 8. Glycosyltransferase activity required either Mn2+ or Mg2+, had a pH optimum of 6.5 and was temperature-dependent. 9. The kinetics of incorporation were complex, probably a result of multiple acceptors or glycosyltransferases whose activities were characterized by a Km of 30 microM for UDP-GlcNAc with a V of 40 pmol x mg protein -1 x min-1 for the highest affinity system and a Km of approximately 2 mM for UDP-GlcNAc with a V of approximately 400 pmol x mg protein-1 x min-1 for the lowest affinity system. 10. Glycosyltransferases using UDP-GlcNAc, uridine diphosphate glucose, uridine diphosphate galactose and guanidine diphosphate mannose as glycosyl donors were observed. Each peptide acceptor was specific for a singloe labelled sugar in the absence of other unlabelled nucleotide sugars. 11. The final extent of incorporation of GlcNAc was due primarily to exhaustion of peptide acceptor. 12. An inhibitor of UDP-[14C]GlcNAc incorporation into plasma membranes was found in the cytoplasmic fraction.

Synthesis of beta-(1-->3)-Glucan from Extracellular Uridine Diphosphate Glucose as a Wound Response in Suspension-cultured Soybean Cells.

Soybean (Glycine max) suspension-cultured cells were incubated with 600 micromolar uridine diphosphate [(14)C]glucose, and the incorporation into alkali-insoluble material was studied. When the cells were kept in suspension by shaking on a linear shaker, the incorporation was very low. The incorporation was stimulated 30-fold when the cells were continually resuspended by stirring with a narrow glass rod. The stirring procedure was shown to damage some of the cells, and the incorporation appeared to be a wound response. The alkali-insoluble material formed was a beta-(1-->3)-glucan, and it was synthesized from uridine diphosphate glucose which did not penetrate through the plasma membrane of intact cells. The synthetase activity was probably induced by the stirring procedure. No evidence for cellulose synthesis from extracellular uridine diphosphate glucose was obtained.

Dolichyl monophosphate and its sugar derivatives in plants.

A glucose acceptor was isolated from soya beans by extraction with chloroform/methanol (2:1, v/v), followed by DEAE-cellulose column chromatography of the extract. This acceptor could not be distinguished from liver dolichyl monophosphate by t.l.c. It could replace dolichyl monophosphate as a mannose acceptor with a liver enzyme and its glucosylated derivative could replace dolichyl monophosphate glucose as a glucose donor in the same system. These results, together with those already reported [Pont Lezica, Brett, Romero Martinez & Dankert (1975) Biochem, Biophys. Res. Commun. 66, 980-987], indicate that the acceptor from soya bean is a dolichyl monophosphate. Gel filtration of its glucosylated derivative on Sephadex G-75 in the presence of sodium deoxycholate indicated that the acceptor contained 17 or 18 isoprene units. An enzyme preparation from pea seedlings was shown to use endogenous acceptors to form lipid phosphate sugars containing mannose and N-acetylglucosamine from GDP-mannose and UDP-N-acetylglucosamine. Chromatographic and degradative techniques indicated that the compounds formed were lipid monophosphate mannose, lipid pyrophosphate N-acetylglucosamine, lipid pyrophosphate chitobiose and a series of lipid pyrophosphate oligosaccharides containing both mannose and N-acetylglucosamine. None of these compounds was degraded by catalytic hydrogenation, and so the lipid moiety in each case was probably an alpha-saturated polyprenol. The endogenous acceptors for mannose and N-acetylglucosamine in peas may therefore be dolichyl monophosphate, as has been found in mammalian systems.

The formation of oligoglucans linked to lipid during synthesis of beta-glucan by characterized membrane fractions isolated from peas.

Membrane fractions were obtained from peas roots by using a method that permitted the isolation of a fraction rich in relatively intact dictyosome stacks. No chemical fixatives were used. The method involved incubation of the roots with cellulase, followed by gentle homogenization and sucrose-density-gradient fractionation of the homogenate. The fractions were characterized by electron microscopy. All fractions were enzymically active in incorporating glucose from UDP-glucose into water-insoluble glycolipids containing both single glucose residues and glucose oligosaccharides. Some or all of the linkages of glucose to lipid were through phosphate esters. A substance containing glucose oligosaccharides attached to or very strongly adsorbed on to protein was also formed. The membrane fractions also incorporated glucose from UDP-glucose into alkali-soluble and alkali-insoluble beta-glucans, which like the oligosaccharides contained beta(1leads to 3) and beta-(1leads to4) linkages. The distribution of the enzymic activities and the chemical properties of the lipid-linked and protein-linked oligosaccharides suggest that they may be intermediates in beta-glucan synthesis. The synthetic activity is associated with smooth-membrane vesicles which may be derived from the plasma membrane.