Studies on initiation and development of the partner association inGeosiphon pyriforme (Kütz.) v. Wettstein,a unique endocytobiotic system of a fungus (Glomales) and the cyanobacteriumNostoc punctiforme (Kütz.) Hariot

Summary Phagocytosis ofNostoc filaments byGeosiphon, a fungus closely related to AM forming Glomales, was observed under light microscopes. Incorporation can only be performed ifNostoc primordia come into contact with growing hyphal tips of the fungus. The fungal wall just below the apex softens, and fungal cytoplasm is bulged out repeatedly covering the vegetativeNostoc cells but not the heterocytes. New heterocytes are differentiated by the internalised filament whose cells can increase up to ten times in volume after recovering from incorporation strain. TheNostoc cells are coated stepwise by short finger-shaped protuberances of the fungal hypha. These hernia-like outgrowths first remain separated, after 1 to 2 days they merge. Adjacent hyphal walls inside the complex covering disintegrate. Periphal fungal wall portions are united to form a smooth strong outer envelope. Internalisation is categorised as phagocytosis. The partnership is partly specific,Nostoc strains capable of living endocytobiotically are often partners in other symbioses besidesGeosiphon.Abbreviations AM arbuscular mycorrhiza (formerly VAM vesicular arbuscular mycorrhiza) - DIC differential interference contrast - LD light/dark Dedicated to Prof. Dr. Dr. h.c. Eberhard Schnepf on the occasion of his retirement     

Geosiphon pyriforme,an Endosymbiotic Association of Fungus and Cyanobacteria: the Spore Structure Resembles that of Arbuscular Mycorrhizal (AM) Fungi

The zygomycete Geosiphon pyriforme is the only known endocyanosis of a fungus. The Nostoc spp. filaments are included in photosynthetically active and nitrogen fixing, multinucleated bladders, which grow on the soil surface. The spores of the fungus are white or slightly brownish. They are about 250 μm in diameter and develop singly on hyphal ends or, less frequently, intercalarly. The wall of the spores consists of a thin innermost layer, a laminated inner layer with a thickness of about 10–13 μm, and an evanescent outer layer. The laminated layer is composed of helicoidally arranged microfibrils, and is separated from the evanescent outer layer by a thin electron-dense sublayer. Polarisation microscopy indicates the occurrence of chitin. Shape and wall ultrastructure of the Geosiphon spores and their cytoplasm resemble that of Glomus spores, but are different from that of other genera of the Glomales and Endogonales. Germination occurs by a single thick hyphal outgrowth directly through the spore wall. Like various AM forming fungi, Geosiphon pyriforme contains endocytic bacteria-like organisms, which are not surrounded by a host membrane. Our observations indicate that Geosiphon is a potential AM fungus.     

Characterization of theGeosiphon pyriforme symbiosome by affinity techniques: confocal laser scanning microscopy (CLSM) and electron microscopy

Summary Geosiphon pyriforme represents a photoautotrophic endosymbiosis of aGlomus-like fungus with the cyanobacteriumNostoc punctiforme. The fungus forms unicellular bladders of up to 2 mm in length and 0.5 mm in diameter growing on the soil surface and harboring the endosymbioticNostoc filaments. The cyanobacteria are located in a compartment (the symbiosome) bordered by a host membrane. The space between this symbiosome membrane (SM) and theNostoc cell wall is filled with an about 30–40 nm thick layer of amorphous material, which is present also in the regions of the symbiosome where noNostoc filaments are located. At these sites the amorphous material consists of a 20–30 nm thick layer separating the SM. The region between the SM and the cyanobacterium is defined as symbiosome space (SS). Fungal bladders, hyphae and free livingNostoc were analyzed by affinity techniques as well as the material occurring in the SS. FITC-coupled lectins with sugar specificity to -D-mannosyl/-D-glucosyl (Con A), N-acetyl--D-glucosamine oligomers (WGA), -L-fucosyl (UEA-I), -D-galactosyl (RCA-120), -D-galactosyl (BS-I-B₄), N-acetyl--D-galactosamine (HPA), and sialic acid (EBL) residues were tested. WGA binding and calcofluor white staining demonstrated that the bladder wall as well as the SS contain fibrillar chitin. Of the other lectins only Con A clearly labeled the symbiosome. On the contrary, the lectin binding properties of the slime produced by free livingNostoc-colonies indicate the presence of mannose, fucose, GalNAc, sialic acid, and galactose, while chitin or GlucNAc-oligomers could not be detected. The symbiosome was also investigated electron microscopically. WGA-gold binding confirmed the presence of chitin, while a slight PATAg reaction indicated some polysaccharidic molecules within the SS. Our results show that the amorphous material within the SS contains molecules typical of the fungal cell wall and suggest that the SM is related to the fungal plasma membrane. The applied lectins all bind to the hyphal surface, indicating a high molecular complexity. Mannosyl, -galactosyl, and sialic acid residues are strongly exposed at the outer cell wall layer, whereas GlucNAc, GalNAc, and -galactosyl residues seem to be present in smaller amounts. The symbiotic interface established between the fungus andNostoc inGeosiphon shows many similarities to that occurring between fungi and root cells in arbuscular mycorrhizas.Abbreviations AM arbuscular mycorrhiza - BS-I-B₄ Bandeiraea simplicifolia lectin I isolectin B₄ - CLSM confocal laser scanning microscopy - Con A Concanavalin A - EBL elderberry bark lectin I - FITC fluorescein isothiocyanate - HPA Helix pomatia agglutinin - PATAg periodic acid-thiocarbohydrazide-Ag proteinate - SM symbiosome membrane - SS symbiosome space - RCA-120 Ricinus communis agglutinin 120 - UEA-I Ulex europaeus agglutinin I - WGA wheat germ agglutinin Dedicated to Professor Dr. Peter Sitte at the occasion of his 65th birthday     

Geosiphon pyriforme,a fungus forming endocytobiosis withNostoc (Cyanobacteria), is an ancestral member of the glomales: Evidence by SSU rRNA Analysis

Geosiphon pyriforme inhabiting the surface of humid soils represents the only known example of endocytobiosis between a fungus (Zygomycotina; macrosymbiont) and cyanobacteria (Nostoc; endosymbiont). In order to elucidate the taxonomical and evolutionary relationship ofGeosiphon pyriforme to fungi forming arbuscular mycorrhiza (AM fungi), the small-subunit (SSU) ribosomal RNA genes ofGeosiphon pyriforme andGlomus versiforme (Glomales; a typical AM fungus) were analyzed and aligned with SSU rRNA sequences of several Basidiomycetes, Ascomycetes, Chytridiomycetes, and Zygomycetes, together with all AM-fungal (Glomales) sequences published yet. The distinct group of the order Glomales, which includesGeosiphon, does not form a clade with any other group of Zygomycetes. Within the Glomales, two main lineages exist. One includes the families Gigasporaceae and Acaulosporaceae; the other one is represented by the genusGlomus, the members of which are very divergent.Glomus etunicatum andGeosiphon pyriforme both form independent lineages ancestral to the Glomales. The data provided by the present paper confirm clearly thatGeosiphon represents a fungus belonging to the Glomales. The question remains still open as to whether or notGeosiphon is to be placed within or outside the genusGlomus, since this genus is probably polyphyletic and not well defined yet.Geosiphon shows the ability of aGlomus-like fungus to form a “primitive” symbiosis with a unicellular photcautotrophic organism, in this case a cyanobacterium, leading to the conclusion that a hypothetical association of aGlomus-like fungus with a green alga as a step during the evolution of the land plants appears probable. Correspondence to: H. Gehrig     

A cohesion/tension model for the gating of aquaporins allows estimation of water channel pore volumes in Chara

The water permeability (hydraulic conductivity; Lp) of turgid, intact internodes of Chara corallina decreased exponentially as the concentration of osmolytes applied in the medium increased. Membranes were permeable to osmolytes and therefore they could be applied on both sides of the plasma membrane at concentrations of up to 2.0 m (5.0 MPa of osmotic pressure). Organic solutes of different molecular size (molecular weight, MW) and reflection coefficients (σ_s) were used [heavy water HDO, MW: 19, σ_s: 0.004; acetone, MW: 58, σ_s: 0.15; dimethyl formamide (DMF), MW: 73, σ_s: 0.76; ethylene glycol monomethyl ether (EGMME), MW: 76, σ_s: 0.59; diethylene glycol monomethyl ether (DEGMME), MW: 120, σ_s: 0.78 and triethylene glycol monoethyl ether (TEGMEE), MW: 178, σ_s: 0.80]. The larger the molecular size of the osmolyte, the more efficient it was in reducing cell Lp at a given concentration. The residual cell Lp decreased with increasing size of osmolytes. The findings are in agreement with a cohesion/tension model of the osmotic dehydration of water channels (aquaporins; AQPs), which predicts both reversible exponential dehydration curves and the dependence on the size of osmolytes which are more or less excluded from AQPs (Ye, Wiera & Steudle, Journal of Experimental Botany 55, 449–461, 2004). In the presence of big osmolytes, dehydration curves were best described by the sum of two exponentials (as predicted from the theory in the presence of two different types of AQPs with differing pore diameters and volumes). AQPs with big diameters could not be closed in the presence of osmolytes of small molecular size, even at very high concentrations. The cohesion/tension theory allowed pore volumes of AQPs to be evaluated, which was 2.3 ± 0.2 nm³ for the narrow pore and between 5.5 ± 0.8 and 6.1 ± 0.8 nm³ for the wider pores. The existence of different types of pores was also evident from differences in the residual Lp. Alternatively, pore volumes were estimated from ratios between osmotic (P_f) and diffusional (P_d) water flow, yielding the number of water molecules (N) in the pores. N-values ranged between 35 and 60, which referred to volumes of 0.51 and 0.88 nm³/pore. Values of pore volumes obtained by either method were bigger than those reported in the literature for other AQPs. Absolute values of pore volumes and differences obtained by the two methods are discussed in terms of an inclusion of mouth parts of AQPs during osmotic dehydration. It is concluded that the mouth part contributed to the absolute values of pore volumes depending on the size of osmolytes. However, this can not explain the finding of the existence of two different types or groups of AQPs in the plasma membrane of Chara.     

Cell-wall-bound oxidases from tobacco (Nicotiana tabacum) xylem participate in lignin formation

A band of cells closest to the cambium in the xylem of tobacco (Nicotiana tabacum L. cv. Samsun) stems oxidized 2,2-azinobis-(3-ethylbenzo-thiazoline-6-sulphonate) (ABTS), o-dianisidine and syringaldazine in the absence of exogenously added hydrogen peroxide. The oxidation was not prevented by catalase which suggests that the oxidation is not dependent on the production and utilisation of endogenous hydrogen peroxide by cell-wall peroxidases. Cell walls, isolated from tobacco xylem, also oxidized these substrates in the absence of added hydrogen peroxide. The cell walls consumed molecular oxygen whilst oxidizing a range of compounds including coniferyl alcohol. The substrate preference and sensitivity to inhibitors suggest the presence of laccasetype polyphenol oxidases (p-diphenol:O₂ oxidoreductase EC 1.14.18.1) which are covalently bound to the wall. The oxidation of coniferyl alcohol by the xylem cell walls was confirmed by assays based on the disappearance of coniferyl alcohol and was not affected by the presence of 500 units·mi^-1 catalase or Superoxide dismutase. Prolonged incubation of cell walls with coniferyl alcohol led to the production of a yellow-orange water-insoluble material that precipitated with the cell walls. Although a proportion of this material was soluble in methanol, the majority was tightly associated with the cell walls. These coloured cell walls had elevated lignin contents when assayed by the acetyl-bromide method. Fourier transforminfrared spectroscopic analysis of the coloured cell walls indicated that the increased lignin content is due to the deposition of guaiacyl-type lignin. Digestion of the xylem cell walls with Driselase, a mixture of fungal glycases, produced a wall residue that had a dramatically reduced ability to oxidize ABTS in the absence of added H₂O₂. However, oxidase activity could not be detected in the Driselase-solubilized extract, although small amounts of oxidase activity could be recovered from the Driselaseresistant wall residue by extraction in 3 M CaCl₂.Abbreviations ABTS 2,2-azinobis-(3-ethylbenzo-thiazoline-6-sulphonate) - dl-DOPA 3-(3,4-dihydroxyphenyl)-alanine - FTIR Fourier transform infra-red - o-D o-dianisidine - o-pD o-phenylenediamine - SYR syringaldazine The authors acknowledge funding from the Scottish Office Agriculture and Food Department. They would like to thank Professor J.R. Hillman for his support, Dr. G.D. Lyon for his help and advice with the oxygen electrode and Mrs F. Carr for lignin determinations.     

Loss of capacity for acid-induced wall loosening as the principal cause of the cessation of cell enlargement in light-grown bean leaves

Cell enlargement in primary leaves of bean (Phaseolus vulgaris L.) can be induced, free of cell divisions, by exposure of 10-d-old, red-light-grown seedlings to white light. The absolute rate of leaf expansion increases until day 12, then decreases until the leaves reached mature size on day 18. The cause of the reduction in growth rate following day 12 has been investigated. Turgor calculated from measurements of leaf water and osmotic potential fell from 6.5 to 3.5 bar before day 12, but remained constant thereafter. The decline of growth after day 12 is not caused by a decrease in turgor. On the other hand, Instron-measured cell-wall extensibility decreased in parallel with growth rate after day 12. Two parameters influencing extensibility were examined. Light-induced acidification of cell walls, which has been shown to initiate wall extension, remained constant over the growth period (days 10–18). Furthermore, cells of any age could be stimulated to excrete H⁺ by fusicoccin. However, older tissue was not able to grow in response to fusicoccin or light. Measurements of acid-induced extension on preparations of isolated cell walls showed that as cells matured, the cell walls became less able to extend when acidified. These data indicate that it is a decline in the capacity for acid-induced wall loosening that reduces wall extensibility and thus cell enlargement in maturing leaves.Abbreviations and symbols FC fusicoccin - P turgor pressure - RL red light - WEx wall extensibility - WL white light - P _w leaf water potential - P _s osmotic potential     

The cell wall of Chlamydomonas reinhardtii gametes: Composition,structure and autolysin-mediated shedding and dissolution

The cell walls of Chlamydomonas gametes are multilayered structures supported on frameworks of polypeptides extending from the plasma membrane. The wall-polypeptide catalogue reported by Monk et al. (1983, Planta 158, 517–533) and extended by U.W. Goodenough et al. (1986, J. Cell Biol. 103, 405–417) was re-evaluated by comparative analysis of mechanically isolated cell walls purified from several strains. The extracellular locus of wall polypeptides was verified by in vivo iodogen-catalysed iodination and by autolysin-mediated elimination of the bulk of these polypeptides from the cell surface. Three (w15, w16, w17) and possibly four (w14) polypeptides were located to the most exterior aspect of the wall because of their susceptibility to Enzymobeadcatalysed iodination and their retention by a cell-wall-less mutant. The composition of shed walls stabilised with ethylenediaminetetraacetic acid during natural mating and kinetic analysis of the dissolution of walls purified from a bald-2 mutant demonstrated the rapid and specific destruction of polypeptide w3. Differential solubilisation of wall polypeptides occurred after loss of w3. Wall dissolution, characterised by the generation of fishbone structures from the W2 layer, gave as many as four additional polypeptides. Charged detergents and sodium perchlorate extracted a comparable range of polypeptides at room temperature from mechanically isolated walls, i.e. components of the W4–W6 layers, hot sodium dodecyl sulphate solubilised framework polypeptides, while reducing agent was required to solubilise the W2 layer. A model of wall structure is presented.Abbreviations DTE dithioerythritol - EDTA ethylenediaminetetraacetic acid - M_r relative molecular mass - SDS-PAGE sodium dodecyl sulphate-polyacrylamide gel electrophoresis - Tris 2-amino-2-(hydroxymethyl)-1,3-propanediol     

Water permeability of Betula periderm

The water permeability of periderm membranes stripped from mature trees of Betula pendula Roth was investigated. The diffusion of water was studied using the system water/membrane/water, and transpiration was measured using the system water/membrane/water vapor. Betula periderm consists of successive periderm layers each made up of about 5 heavily suberized cell layers and a varying number of cell layers that are little suberized, if at all. It is shown that these layers act as resistances in series. The permeability coefficient of the diffusion of water (P _d) can be predicted with 79% accuracy from the reciprocal of the membrane weight (x in mg cm^-2) by means of the linear equation P _d=14.69·10^-7 x-0.73·10^-7. For example, the P _d of a periderm membrane having a weight of 10 mg cm^-2 (approx. 250 m thick) is 7.4·10^-8 cm s^-1, which is comparable to the permeability of cuticles. This comparison shows that on a basis of unit thickness, Betula periderm is quite permeable to water as cuticles have the same resistance with a thickness of only 0.5 to 3 m. It is argued that this comparatively high water permeability of birch periderm is due to the fact that middle lamellae and the primary walls of periderm cells are not at all, or only incompletely suberized and, therefore, form a hydrophilic network within which the water can flow. This conclusion is based on the following observations: (1) Middle lamellae and primary walls stain strongly with toluidine blue, which shows them to be polar. (2) If silver ions are added as tracer for the flow of water, they are found only in the middle lamellae, primary walls, and in plasmodesmata, while no silver can be detected in the suberized walls. (3) Permeability coefficients of transpiration strongly depend on water activity. This shows conclusively that water flows across Betula periderm via a polar pathway. It is further argued that liquid continuity is likely to be maintained under all physiological conditions in the network formed by middle lamellae and primary walls. On the other hand, the lumina of periderm cells, intercellular air spaces in the lenticels, and even the pores in the suberized walls (remainders of plasmodesmata) will drain at a humidity of 95% and below. Due to the presence of intercellulars the permeability coefficient of lenticels is much greater than that of the periderm. A substantial amount of the total water, therefore, flows as vapor through lenticels even though they cover only 3% of the surface.Abbreviations PM perideron membrane - P _d permeability coefficient for diffusion of water - P _tt permeability coefficient of transpiration - MES (N-morpholino)ethane sulfonic acid     

A proton nuclear magnetic resonance study of the physical changes in growing plant cell walls

Changes in broadline proton nuclear magnetic resonance parameters of cell walls during growth of etiolated hypocotyls of bean (Phaseolus vulgaris L.) indicate that cell wall structure becomes more rigid during development. Most of the changes are completed in the first 6 cm below cotyledon insertion and are correlated with increased restriction of proton movements in regions of dense polymer packing.Abbreviations FID free induction decay - M₂ second moment - M_2interpair interpair second moment - NMR nuclear magnetic resonance - T_1D dipolar relaxation time - T₂ spin-spin relaxation time This work was supported by grants from Natural Sciences and Engineering Research Council of Canada to A.L.M., I.E.P.T. and M. Bloom.     

Characterization of the cell wall of the unicellular cyanobacterium Synechocystis PCC 6714

Cell walls free of cytoplasmic- and thylakoid membranes were isolated from Synechocystis PCC 6714 by sucrose density gradient centrifugation and extraction with Triton X-100. The Triton-insoluble cell wall fraction retained the multilayered fine structure. Peptidoglycan, proteins, polysaccharides, lipopolysaccharides, lipids and carotenoids were found as constituents of the cell wall. Polypeptide and lipid patterns of cell walls were completely different from that of the cytoplasmic/thylakoid membrane fraction. The purified cell walls contained about twelve outer membrane proteins. The two major polypeptides (M_r 67,000 and 61,000) were found to be associated with the peptidoglycan by ionic interactions.Myxoxanthophyll (major carotenoid), related carotenoid-glycosides and zeaxanthin were the predominating carotenoids of the cell wall of Synechocystis PCC 6714 over echinenone and -carotene. A polar unknown carotenoid was observed, the absorption spectrum of which resembled that of myxoxanthophyll. It was exclusively found in cell walls, but not in the cytoplasmic/thylakoid membrane fraction.Abbreviations Hep heptose - DGDG digalactosyldiglyceride - MGDG monogalactosyldiglyceride - SL sulfolipid - PC phosphatidylcholin - PG phosphatidylglyceride Dedicated to Prof. Dr. G. Drews on the occasion of his 60th birthday     

An improved method of measuring photosynthetic electron transport in Euglena under in vivo conditions

A method is described to measure photochemical activity in intact cells of Euglena under in vivo conditions. The method employs a cell wall digesting enzyme (cellulysin) to induce enough permeability in the cell walls and membranes in order to allow dyes, commonly used to investigate light-dependent electron transport reactions to enter, but without inducing a concomittant efflux of metabolites. Between 1 and 2 h of incubation in 5% (w/v) cellulysin provided conditions which allowed measurement of photosystem I-, II- and I+II-dependent electron transport with rates up to 600% higher than in control cells; whereas other cell wall degrading enzymes (cellulase and pectinase) still did not increase the entry of the dyes. Cellulysin up to 2 h of incubation had little or no effect on whole cell respiration, photosynthetic O₂ evolution, or the export of potassium and (¹⁴C) labeled compounds out of cells; therefore cellulysin obviously did not change the normal habit or physiology of Euglena. Cellulysin (4 h digestion), cellulase and pectinase (2–4 h of incubation) on the other hand led to a lowering of respiration and light-dependent O₂ evolution, and increased the efflux of K⁺, but apparently decreased that of (¹⁴C)labeled fixation products.Abbreviations DBMIB dibromothymoquinone - DCPIP 2,6-dichlorophenol-indophenol - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - DMMIB 2,3-dimethyl-5,6-methylenedioxy-p-benzoquinone - MV methylviologen - PSI photosystem I - PS II photosystem II     

Carotenoids in the outer cell-wall layer of Scenedesmus (Chlorophyceae)

Scenedesmus obliquus, strain 633, which synthesizes ketocarotenoids and sporopollenin, also forms pink-red-colored cell walls. Both the cell walls left over after autospore liberation and those from homogenates of disrupted green cells have similar carotenoid pigmentation. Canthaxanthin, astaxanthin, an unidentified ketocarotenoid, and lutein were found as integral cell wall components. They are bound to the outer (trilaminar) layer of the complete cell wall which also contains sporopollenin.Abbreviations CWH complete cell walls isolated from the homogenates - CWM maternal cell walls accumulated in the medium - KC ketocarotenoid - SC secondary carotenoids - SP sporopollenin     

Microtubules and morphogenesis in stomata of the water fernAzolla: An unusual mode of guard cell and pore development

Summary A mature stomate of the water fernAzolla consists of a single apparently unspecialized annular guard cell (GC) with two nuclei surrounding an elongated pore aligned longitudinally in the leaf. During development, the guard mother cell develops a preprophase band (PPB) of microtubules (MTs) oriented transverse to the leaf axis. This is followed by a cell plate which fuses with the parental walls at the PPB site. Subsequently only the central part of the cell plate is consolidated, while the parts to either side become perforated and tenuous and may disperse completely, forming a single composite GC.Meanwhile, a dense array of MTs appears along both faces of the central part of the new wall, oriented normal to the leaf surface. Further MT arrays radiate out across the periclinal walls from the region of the consolidated cell plate. Putative MT nucleating sites are seen along the cell edges between these anticlinal and periclinal arrays. Polarized light microscopy reveals cellulose deposition parallel to the periclinal MT arrays. At the same time lamellar material is deposited within the new anticlinal wall. As the GC complex elongates, a split appears in these lamellae creating an initially transverse slit which then opens up to become first circular and ultimately an elongated pore aligned in the long axis of the leaf,i.e., at right angles to the wall in which it originated. The radiating pattern of cellulose microfibrils in the periclinal walls contributes to the shaping of the pore. Elongation at the apical and basal ends of the GC is restricted by longitudinal microfibril orientation, while that at the sides is facilitated by transverse alignment.     

Cell wall polysaccharides from Talaromyces species

The neutral sugars and amino sugars, released by acid hydrolysis of walls and polysaccharidic fractions, of six species of Talaromyces and the infrared spectra have been used to study their interspecific relationships. In whole cell walls neutral sugars ranged from 23 to 39.6% dry weight and were identified as glucose, galactose and mannose. Glucosamine varied from 8 to 19.8% in the samples. Galactosamine (2% or less) was found in T. emersonii and T. rotundus and no galactosamine in the other species. Sequential fractionation of the cell walls with alkali and acid gave several polysaccharidic fractions. The main differences among species were found in the alkali-soluble fraction at 20° (F1). This fraction represented 8 to 33.2% of the whole cell wall and was characterized as an -glucan in T. bacillisporus, T. emersonii, T. luteus and T. rotundus (Group A) and as a -galactofuranosyl containing glucan in T. ohiensis and T. stipitatus (Group B). The alkali-insoluble residue (F4) represented the bulk of the cell wall in all species tested (33.2% to 57.3%) and was characterized as a -glucan/chitin complex. The results may indicate degrees of interspecific relationship in the genus Talaromyces.Abbreviations CWM cell wall material - GLC gas-liquid chromatography - IR infrared - wt weight - CBS Centraal Bureau voor Schimmelcultures (Baarn. The Netherlands) - Ara arabinose - Xyl xylose - Man mannose - Gal galactose - Glc glucose - GlcNH₂ glucosamine - GalNH₂ galactosamine     

Location of the major barriers to water and ion movement in young roots of Zea mays L.

The main barriers to the movement of water and ions in young roots of Zea mays were located by observing the effects of wounding various cell layers of the cortex on the roots' hydraulic conductivities and root pressures. These parameters were measured with a root pressure probe. Injury to the epidermis and cortex caused no significant change in hydraulic conductivity and either no change or a slight decline in root pressure. Injury to a small area of the endodermis did not change the hydraulic conductivity but caused an immediate and substantial drop in root pressure. When large areas of epidermis and cortex were removed (15–38% of total root mass), the endodermis was always injured and root pressure fell. The hydraulic conductance of the root increased but only by a factor of 1.2–2.7. The results indicate that the endodermis is the main barrier to the radial movement of ions but not water. The major barrier to water is the membranes and apoplast of all the living tissue. These conclusions were drawn from experiments in which hydrostatic-pressure differences were used to induce water flows across young maize roots which had an immature exodermis and an endodermis with Casparian bands but no suberin lamellae or secondary walls. The different reactions of water and ions to the endodermis can be explained by the huge difference in the permeability of membranes to these substances. A hydrophobic wall barrier such as the Casparian band should have little effect on the movement of water, which permeates membranes and, perhaps, also the Casparian bands easily. However, hydrophobic wall depositions largely prevent the movement of ions. Several hours after wounding the endodermis, root pressure recovered to some extent in most of the experiments, indicating that the wound in the endodermis had been partially healed.Abbreviations Lp_r hydraulic conductivity of root; T_1/2 = half-time of water exchange between root xylem and external medium This research was supported by a grant from EUROSILVA (project no. 39473C) to E.S., and by a Bilateral Exchange Grant jointly funded by the Deutsche Forschungsgemeinschaft and the Natural Sciences and Engineering Research Council of Canada to C.A.P. We thank Mr. Burkhard Stumpf for his excellent technicial assistance.     

Structure and distribution of lignin in primary and secondary cell walls of maize coleoptiles analyzed by chemical and immunological probes

Lignin is an integral constituent of the primary cell walls of the dark-grown maize (Zea mays L.) coleoptile, a juvenile organ that is still in the developmental state of rapid cell extension. Coleoptile lignin was characterized by (i) conversion to lignothiolglycolate derivative, (ii) isolation of polymeric fragments after alkaline hydrolysis, (iii) reactivity to antibodies against dehydrogenative polymers prepared from monolignols, and (iv) identification of thioacidolysis products typical of lignins. Substantial amounts of lignin could be solubilized from the coleoptile cell walls by mild alkali treatments. Thioacidolysis analyses of cell walls from coleoptiles and various mesocotyl tissues demonstrated the presence of guaiacyl-, syringyl- and (traces of)p-hydroxyphenyl units besidesp-coumaric and ferulic acids. There are tissue-specific differences in amount and composition of lignins from different parts of the maize seedling. Electron-microscopic immunogold labeling of epitopes recognized by a specific anti-guaiacyl/syringyl antibody demonstrated the presence of lignin in all cell walls of the 4-d-old coleoptile. The primary walls of parenchyma and epidermis were more weakly labeled than the secondary wall thickenings of tracheary elements. No label was found in middle lamellae and cell corners. Lignin epitopes appeared first in the tracheary elements on day 2 and in the parenchyma on day 3 after sowing. Incubation of coleoptile segments in H₂O₂ increased the amount of extractable lignin and the abundance of lignin epitopes in the parenchyma cell walls. Lignin deposition was temporally and spatially correlated with the appearance of epitopes for prolinerich proteins, but not for hydroxyproline-rich proteins, in the cell walls. The lignin content of coleoptiles was increased by irradiating the seedlings with white or farred light, correlated with the inhibition of elongation growth, while growth promotion by auxin had no effect. It is concluded that wall stiffness, and thus extension growth, of the coleoptile can be controlled by lignification of the primary cell walls. Primary-wall lignin may represent part of an extended polysaccharide-polyphenol network that limits the extensibility of the cell walls.Abbreviations G, S, H guaiacyl, syringyl andp-hydroxyphenyl constituents of lignin - HRGP hydroxyproline-rich glycoprotein - LTGA lignothioglycolic acid - PRP proline-rich protein Dedicated to Professor Benno Parthier on occasion of his 65th birthdayDeceased 7 November 1996     

Molecular phylogeny,taxonomy, and evolution of Geosiphon pyriformis and arbuscular mycorrhizal fungi

Geosiphon pyriformis(Kütz.) v. Wettstein is the only known example of a fungus living in endocytobiotic association with a cyanobacterium. The close phylogenetic relationship of Geosiphonwith some arbuscular mycorrhizal fungi (AMF) and the phylogenetic position of Geosiphonare shown in detail. Comprehensive small subunit (SSU) rRNA sequence analyses allow the erection of a new, molecular phylogeny-based taxonomic system for the AMF, including Geosiphon (Geosiphonaceae). Within the recently described phylum Glomeromycota (with one class, Glomeromycetes), a system including four orders was proposed. The erection of several new families will also be necessary. Evolutionary implications are discussed, referring to different possibilities of the influence of AMF on the colonization of the terrestrial habitat by plants.     

Chemical composition of Eubacterium alactolyticum cell wall peptidoglycan

The mechanism of lysis of Eubacterium alactolyticum cell walls by Streptomyces albus G enzyme was studied. The analysis of the peptide terminal groups and peptide subunits isolated from the cell wall digest, released during solubilization of the cell walls, revealed that lytic action of S. albus G enzyme was mainly due to D-alanyl-A₂pm endopeptidase, N-acetylmuramyl-L-alanine amidase, N-acetylmuramidase and N-acetylglucosaminidase. E. alactolyticum cell wall peptidoglycan is composed mainly of glucosamine, muramic acid, D-glutamic acid, L- and D-alanine, meso-diaminopimelic acid and glycine. The peptide subunit consists of L-alanyl-D-glutamyl-meso-A₂pm-D-alanine. D-Alanine is connected directly with the amino group of the meso-A₂pm residue of another peptide subunit. All of the L-amino groups of meso-diaminopimelic acid are involved in cross-linking.The possible structure of the peptide moiety of E. alactolyticum cell wall peptidoglycan is presented.     

Sulfide permeability in the marine invertebrate Urechis caupo

Summary Hydrogen sulfide can reach toxic concentrations in the burrow-water of the echiuran worm Urechis caupo during low tide. Its two large epithelial surfaces, the thick muscular body wall and the thin-walled hindgut are in constant contact with the environment. Hindgut inflation of up to 2 ml water·g wet weight^-1 causes tissue stretch. To determine if these body surfaces present a barrier to sulfide influx, the total permeability coefficient P_T was measured at different degrees of stretch in diffusion chambers at pH 6.0, 7.0, and 8.0, and specific permeability coefficients P_{H 2}S and P_HS ^- were calculated. Both the body wall and the hindgut were more permeable to H₂S than HS^-. The body wall showed no significant increase in sulfide permeability with natural degrees of stretch, and the mean P_{H 2}S and P_HS ^- were 0.17 and 0.063 cm·h^-1, respectively. The sulfide permeability of the hindgut was increased by stretch, with the relative permeability of H₂S increasing faster than that of HS^-. Unstretched hindgut mean P_{H 2}S and P_HS ^- were 0.095 and 0.11 cm·h^-1, respectively, and stretched hindgut mean P_{H 2}S and P_HS ^- were 1.8 and 0.16 cm·h^-1, respectively. A model of sulfide influx in the natural environment indicates that even if the hindgut is kept uninflated, the coelomic fluid of U. caupo would have toxic sulfide concentrations well before the end of a 2-h tidal exposure in the absence of a sulfide elimination mechanism.Abbreviations P permeability coefficient - P_T total permeability coefficient - PD transepithelial potential difference