Steve M. Read

Analysis of the structural heterogeneity of laminarin by electrospray-ionisation-mass spectrometry

Electrospray-ionisation-mass spectrometry (ESIMS) was used in conjunction with chemical derivatisation and degradation procedures to analyse the size heterogeneity and branching structure of laminarin from the brown alga, Laminaria digitata. Laminarin is a beta-(1-->3)-linked D-glucan with occasional beta-(1-->6)-linked branches. Electrospray-ionisation-mass spectrometry of permethylated laminarin distinguished two homologous series of molecules, a minor G-series containing 22-28 glucosyl residues, and a more abundant M-series containing 20-30 glucosyl residues linked to a mannitol residue. The relative abundance of all these molecular species could be determined simultaneously from a single mass spectrum, with a mean mass error of 0.6 atomic mass units and a mean mass accuracy of 0.011%. Both series had a mean degree of polymerisation of 25 glucosyl residues, and an approximately 3:1 molar ratio of M-series to G-series molecules was maintained across the range of molecular sizes. Treatment of laminarin with periodate, followed by reduction with borohydride, degraded terminal glucosyl residues on both the main chain and the branches, and allowed the detection of isomers differing solely in their degree of branching. M-series molecules were thus shown to contain 0, 1, 2, 3 or 4 branches, with an average of 1.3 branches per molecule; branched G-series molecules were also detected. Subsequent treatment with acid (Smith degradation) showed that 75% of the branches were single glucosyl residues. This study thus shows how the speed, resolution and mass accuracy of electrospray-ionisation-mass spectrometry can be used in the detailed structural analysis of a polydisperse polysaccharide.

Location of cellulose and callose in pollen tubes and grains of Nicotiana tabacum

Abstract. The distribution of cellulose and callose in the walls of pollen tubes and grains of Nicotiana tabacum L. was examined by electron microscopy using gold-labelled cellobiohydrolase for cellulose and a (1,3)-β-D-glucan-specific monoclonal antibody for callose. These probes provided the first direct evidence that cellulose co-locates with callose in the inner, electron-lucent layer of the pollen-tube wall, while both polymers are absent from the outer, fibrillar layer. Neither cellulose nor callose are present in the wall at the pollen-tube tip or in cytoplasmic vesicles. Cellulose is first detected approximately 5–15 μm behind the growing tube tip, just before a visible inner wall layer commences, whereas callose is first observed in the inner wall layer approximately 30 μm behind the tip. Callose was present throughout transverse plugs, whereas cellulose was most abundant towards the outer regions of these plugs. This same distribution of cellulose and callose was also observed in pollen-tube walls of N. alata Link et Otto, Brassica campestris L. and Lilium longiflorum Thunb. In pollen grains of N. tabacum, cellulose is present in the intine layer of the wall throughout germination, but no callose is present. Callose appears in grains by 4 h after germination, increasing in amount over at least the first 18 h, and is located at the interface between the intine and the plasma membrane. This differential distribution of cellulose and callose in both pollen tubes and grains has implications for the nature of the β-glucan biosynthetic machinery.

Stimulation of growth of culturedNicotiana tabacum W 38 pollen tubes by poly(ethylene glycol) and Cu(II) salts

SummaryGrowth of pollen tubes ofNicotiana tabacum W 38 in a defined liquid medium buffered at pH 5.9 and containing sucrose, amino-acids, boric acid, salts and an antibacterial agent was stimulated by the addition of poly(ethylene glycol) 6000 (PEG-6000) and Cu(II) salts. In the absence of both these supplements, up to 50% of the hydrated pollen grains did not develop further, and the germinated tubes were slow-growing and abnormal, with thickened walls, kinked growth, and fragile, swollen tips containing granular cytoplasm. Addition of 10–15% (w/v) purified PEG-6000 increased germination to 80–90% and prevented the progressive bursting of pollen grains and tube tips, but growth was still slow and kinked and tips remained swollen. Addition of 30 μM CuSO4 did not stimulate germination or prevent tip bursting, but produced straight-growing tubes with smooth-sided tips resembling the tips of tubes growing through stylar tissue; the free Cu2+ concentration under these conditions was about 1.0 μM due to chelation by amino-acids, and similar tube morphologies were obtained with 1.0–1.5 μM added CuSO4 when NH4Cl replaced the amino-acids. When the medium containing amino-acids was supplemented with both 12.5% PEG-6000 and 30 μM CuSO4, long-term (48 h) growth of straight pollen tubes with smooth-sided tips, thin walls and long ladders of callose plugs was observed; growth occurred at 250 μm/h, approximately 30–40% of the rate observed in the style. Although omission of CuSO4 from this complete medium severely affected tube growth and callose plug deposition, it did not alter the timing of generative-nucleus division, and thus the different parameters associated with the second phase of pollen-tube growth can be uncoupled in culture. High levels of FeSO4 (300 μM) had a similar morphogenetic effect to CuSO4, but addition of 300 μM L-ascorbate or D-iso-ascorbate was required to prevent precipitation of Fe(III) oxide and prolong the stimulation of pollen-tube growth; EDTA removed the morphogenetic effect of both CuSO4 and FeSO4. Further, an impure grade of PEG-4000 was contaminated with an organic morphogen that allowed continued slow growth of pollen tubes with smooth, straight-sided tips in the absence of added CuSO4 or FeSO4, with tube morphology unaffected by ascorbate or EDTA. However, the long-term morphogenetic effect of trace levels of CuSO4 suggests that Cu(II) salts play an important role in pollen-tube development in at least this species ofNicotiana.

Uridine Diphosphate Glucose Metabolism and Callose Synthesis in Cultured Pollen Tubes of Nicotiana alata Link et Otto

Membrane preparations from cultured pollen tubes of Nicotiana alata Link et Otto contain a Ca2+ -independent (1–3)-[beta]-D-glucan (callose) synthase activity that has a low affinity for UDP-glucose, even when activated by treatment with trypsin (H. Schlupmann, A. Basic, S.M. Read [1993] Planta 191: 470–481). Therefore, we investigated whether UDP-glucose was a likely substrate for callose synthesis in actively growing pollen tubes. Deposition of (1–3)-[beta]-glucan occurred at a constant rate, 1.4 to 1.7 nmol glucose min-1, in tubes from 1 mg of pollen from 3 h after germination; however, the rate of incorporation of radioactivity from exogenous [14C]-sucrose into wall polymers was not constant, but increased until at least 8 h after germination, probably due to decreasing use of internal reserves. UDP-glucose was a prominent ultraviolet-absorbing metabolite in pollen-tube extracts, with 1.6 nmol present in tubes from 1 mg of pollen, giving a calculated cytoplasmic concentration of approximately 3.5 mM. Radioactivity from [14C]-sucrose was rapidly incorporated into sugar monophosphates and UDP-glucose by the growing tubes, consistent with a turnover time for UDP-glucose of less than 1 min; the specific radioactivity of extracted UDP-[14C]glucose was equal to that calculated from the rate of incorporation of [14C]sucrose into wall glucans. Large amounts of less metabolically active neutral sugars were also present. The rate of synthesis of (1–3)-[beta]-glucan by nontrypsin-treated pollen-tube membrane preparations incubated with 3.5 mM UDP-glucose and a [beta]-glucoside activator was slightly greater than the rate of deposition of (1–3)-[beta]-glucan by intact pollen tubes. These data are used to assess the physiological significance of proteolytic activation of pollen-tube callose synthase.

A novel callose synthase from pollen tubes of Nicotiana

Pollen-tube cell walls are unusual in that they are composed almost entirely of callose, a (1,3)-β-linked glucan with a few 6-linked branches. Regulation of callose synthesis in pollen tubes is under developmental control, and this contrasts with the deposition of callose in the walls of somatic plant cells which generally occurs only in response to wounding or stress. The callose synthase (uridine-diphosphate glucose: 1,3-β-d-glucan 3-β-d-glucosyl transferase, EC 2.4.1.34) activities of membrane preparations from cultured pollen tubes and suspension-cultured cells of Nicotiana alata Link et Otto (ornamental tobacco) exhibited different kinetic and regulatory properties. Callose synthesis by membrane preparations from pollen tubes was not stimulated by Ca2+ or other divalent cations, and exhibited Michaelis-Menten kinetics only between 0.25 mM and 6 mM uridine-diphosphate glucose (Km 1.5–2.5 mM); it was activated by β-glucosides and compatible detergents. In contrast, callose synthesis by membrane preparations from suspension-cultured cells was dependent on Ca2+, and in the presence of 2 mM Ca2+ exhibited Michaelis-Menten kinetics above 0.1 mM uridine-diphosphate glucose (Km 0.45 mM); it also required a β-glucoside and low levels of compatible detergent for full activity, but was rapidly inactivated at higher levels of detergent. Callose synthase activity in pollen-tube membranes increased ten fold after treatment of the membranes with trypsin in the presence of detergent, with no changes in cofactor requirements. No increase in callose synthase activity, however, was observed when membranes from suspension-cultured cells were treated with trypsin. The insoluble polymeric product of the pollen-tube enzyme was characterised as a linear (1,3)-β-d-glucan with no 6-linked glucosyl branches, and the same product was synthesised irrespective of the assay conditions employed.

Variable retention silviculture in Tasmania's wet forests: ecological rationale, adaptive management and synthesis of biodiversity benefits

Summary The recognition that biodiversity conservation requires more than a system of reserves has led to the need to consider the outcomes of land management actions, such as timber harvesting, in the matrix land outside reserves. The design of harvesting systems can be guided by the natural disturbance regime, which in Tasmanias lowland wet eucalypt forests is infrequent, intense wildfire. Clearfell, burn and sow silviculture has been used since the 1960s for harvesting these forests but, while this system is practical and effectively regenerates eucalypts in harvested coupes, it is predicted to lead to losses at the coupe level of late-successional species and structures that would survive into stands regenerating following natural wildfire. Variable retention silviculture is thus currently being implemented as an alternative to clearfelling in wet old-growth forest on public land (state forest) in Tasmania. In contrast to clearfelling, variable retention has the explicit ecological goal of maintaining some species, habitats and structural legacies from the pre-harvest forest into the harvested and regenerating stand. This paper synthesises biodiversity findings from the Warra Silvicultural Systems Trial (SST), established in 1997, and demonstrates that aggregated retention is the optimal form of variable retention for ensuring coupe-scale persistence (‘lifeboating’) of mature-forest biodiversity. In addition to providing retained forest, aggregates are also designed to facilitate recolonisation of harvested areas by mature-forest species (‘forest influence’), and to provide connectivity across the forest stand. In the last few years, more than 50 aggregated-retention coupes have been harvested in mature forest across Tasmania. Development and implementation of variable retention in Tasmania is an example of active adaptive management, which we describe in relation to five steps for a formalised adaptive management program, indicating how ecological criteria are incorporated in operational guidelines for implementation of aggregated retention.

Requirements for division of the generative nucleus in cultured pollen tubes ofNicotiana

SummaryProduction of sperm cells by division of the generative cell occurs during growth ofNicotiana (tobacco) pollen tubes through the sporophytic tissue of the style, and is associated with transition to the second phase of pollen-tube growth. WhenNicotiana pollen tubes are grown in liquid culture, the extent of generative-nucleus division and the timing of this division depend on the chemical composition of the medium. Addition of reduced forms of nitrogen, either as mixed amino-acids (0.03% w/v of an acid hydrolysate of casein) or as 1 mM ammonium chloride, induces division of the generative nucleus in over 90% of the tubes; 3 mM calcium nitrate does not stimulate division. Individual amino-acids differ in their ability to induce this division. Contaminants in some batches of poly(ethylene glycol), which is a major component of pollen-tube growth media, inhibit generative-nucleus division; this inhibition is greater in the absence of nitrogen, which increases the observed nitrogen-dependence of division. Reduced forms of nitrogen are also required for growth of pollen tubes after division, when callose plugs are deposited. In the absence of nitrogen, growth continues until the point where sperm cell production would normally occur, then ceases. Addition of amino-acids or ammonium chloride thus allows cultured pollen tubes ofNicotiana to progress to their second phase of growth. WhenNicotiana pollen is germinated in a complete culture medium at 25–26°C, sperm nuclei are first observed in the growing tubes after about 10 h, and by about 16 h most of the tubes have undergone division; at lower temperatures, division is delayed. The timing of division also varies between species ofNicotiana, but division occurs similarly in self-compatible and self-incompatible species. Anaphase in an individual pollen tube is calculated to take less than 4 min. The resultant sperm nuclei usually trail behind the vegetative nucleus, but a variety of arrangements of the three nuclei are observed.

Membrane fractionation and enrichment of callose synthase from pollen tubes of Nicotiana alata Link et Otto

Abstract. The callose synthase (UDP-glucose: 1,3-β-d-glucan 3-β-d-glucosyl transferase; EC 2.4.1.34) enzyme (CalS) from pollen tubes of Nicotiana alata Link et Otto is responsible for developmentally regulated deposition of the cell wall polysaccharide callose. Membrane preparations from N. alata pollen tubes grown in liquid culture were fractionated by density-gradient centrifugation. The CalS activity sedimented to the denser regions of the gradient, approximately 1.18 g · ml−1, away from markers for Golgi, endoplasmic reticulum and mitochondria, and into fractions enriched in ATPase activity and in membranes staining with phosphotungstic acid at low pH. This suggests that pollen-tube CalS is localised in the plasma membrane. Callose synthase activity from membranes enriched by downward centrifugation was solubilised with digitonin, which gave a 3- to 4-fold increase in enzyme activity, and the solubilised activity was then enriched a further 10-fold by product entrapment. The complete procedure gave final CalS specific activities up to 1000-fold higher than those of pollen-tube homogenates. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed that several polypeptides co-fractionated with CalS activity through purification, with a polypeptide of 190 kDa being enriched in product-entrapment pellets.

Activation of Pollen Tube Callose Synthase by Detergents (Evidence for Different Mechanisms of Action)

In pollen tubes of Nicotiana alata, a membrane-bound, Ca2+-independent callose synthase (CalS) is responsible for the biosynthesis of the (1,3)-[beta]-glucan backbone of callose, the main cell wall component. Digitonin increases CalS activity 3- to 4-fold over a wide range of concentrations, increasing the maximum initial velocity without altering the Michaelis constant for UDP-glucose. The CalS activity that requires digitonin for assay (the latent CalS activity) is not inhibited bythe membrane-impermeant, active-site-directed reagent UDP-pyridoxal when the reaction is conducted in the absence of digitonin. This is consistent with digitonin increasing CalS activity bythe permeabilization of membrane vesicles. A second group of detergents, including 3-[(3-cholamidopropyl)dimethylammonio]-1-propane-sulfonate (CHAPS), Zwittergent 3–16, and 1-[alpha]-lysolecithin, activate pollen tube CalS 10- to 15-fold, but only over a narrow range of concentrations just below their respective critical micellar concentrations. This activation could not be attributed to any particular chemical feature of these detergents. CHAPS increases maximum initial velocity and decreases the Michaelis constant for UDP-glucose and activates CalS even in the presence of permeabilizing concentrations of digitonin. Inhibition studies with UDP-pyridoxal indicate that activation by CHAPS occurs by recruitment of previously inactive CalS molecules to the pool of active enzyme. The activation of pollen tube CalS by these detergents therefore resembles activation of the enzyme by trypsin.

Role of a callose synthase zymogen in regulating wall deposition in pollen tubes of Nicotiana alata Link et Otto

Abstract. The callose synthase (CalS) activity of membrane preparations from cultured Nicotiana alata Link & Otto pollen tubes is increased several-fold by treatment with trypsin in the presence of digitonin, possibly due to activation of an inactive (zymogen) form of the enzyme. Active and inactive forms of CalS are also present in stylar-grown tubes. Callose deposition was first detected immediately after germination of pollen grains in liquid medium, at the rim of the germination aperture. During tube growth the 3-linked glucan backbone of callose was deposited at an increasing rate, reaching a maximum of 65 mg h−1 in tubes grown from 1 g pollen. Callose synthase activity was first detected immediately after germination, and then also increased substantially during tube growth. Trypsin caused activation of CalS throughout a 30-h time course of tube growth, but the degree of activation was higher for younger pollen tubes. Over a 10-fold range of callose deposition rates, the assayed CalS activity was sufficient to account for the rate of callose deposition without trypsin activation, implying that the form of CalS active in isolated membranes is responsible for callose deposition in intact pollen tubes. Sucrose-density-gradient centrifugation separated a lighter, intracellular membrane fraction containing only inactive CalS from a heavier, plasma-membrane fraction containing both active and inactive CalS, with younger pollen tubes containing relatively more of the inactive intracellular enzyme. The increasing rate of callose deposition during pollen-tube growth may thus be caused by the transport of inactive forms of CalS from intracellular membranes to the plasma membrane, followed by the regulated activation of these inactive forms in this final location.