The Synthesis of Cellulose Microfibrils by Particulate Fractions Released from Acetobacter xylinum by Washing

Washing A. xylinum whole cells in 0.01 m phosphate-0.003 m citrate,pH 6.2, leads to the release of particulate fractions whichretain the ability to synthesize cellulose microfibrils fromglucose and from UDPG. These fractions contain both outer andcytoplasmic membrane fragments. Frccze-etching shows the microfibrilsto arise from outer membrane vesicles. A scheme to describethe synthesis of cellulose microfibrils by A. xylinum is proposed.     

An Electron Microscope Examination of Acetobacter xylinum Showing the Ultrastructure of the Cells and the Association of Cellulose Microfibrils

A surface-pellicle-forming strain of A. xylinum was examinedby electron microscopy. Both thin-sections and freeze-etch replicasshowed the ultrastructure of the cells to be typically Gram-negative,the envelope consisting of two membranes with the pcptidoglycanlayer between. The cells did not possess a capsule. Thin-sectionsof cells stained with ruthenium-red showed specific depositslocalized within the periplasm. Cellulose microfibrils wereseen to arise directly from the cell surface, but each cellformed only a limited number of microfibrils. Frecze-etch replicassuggested that the microfibrils arose from particles locatedon or within the outer membrane.     

Changes in the Arrangement of Microtubules and Microfibrils in Differentiating Conifer Tracheids During the Expansion of Cells

The arrangements of microtubules and the cellulose microfibrilsof radial walls in tracheids of Abies sachalinensis Mastersduring the expansion of cells were examined by immunofluorescenceand field-emission scanning electron microscopy. The radialdiameter of tracheids increased to three to four times thatof cambial initial cells. Microfibrils on the innermost surfaceof primary walls of conifer tracheids at early stages were notwell ordered and most of the microfibrils were oriented longitudinally.As each cell expanded, microfibrils in the process of depositionwere still not well ordered but their orientation changed fromlongitudinal to transverse. When cell expansion ceased, microfibrilswere well ordered and oriented transversely. Cortical microtubulesshowed a change in orientation similar to that of the microfibrils.These results indicate that the orientation of cortical microtubulesis correlated with that of microfibrils as they are being laiddown and with cell morphogenesis in conifer tracheids.Copyright1995, 1999 Academic Press Microfibril, microtubule, tracheid, cell expansion, Abies sachalinensis Masters, field-emission scanning electron microscopy, immunofluorescence microscopy     

Modification in Cell Shape Unrelated to Cellulose Microfibril Orientation in Growing Thallus Cells of Chaetomorpha moniligera

Cellulose microfibril orientation patterns in thallus cellsof Chaetomorpha moniligera were studied, and the relationshipbetween the microfibril and the peripheral microtubule arrangementsduring cell-shape modification by colchicine was examined. Inthe cuttings from growing thalli, linearly arranged cylindricalcells developed into cask-shaped cells during 4–6 daysof culture at 27?C. In the cylindrical cells, microfibrils formingthe innermost portion of the wall were arranged alternatelyin longitudinal and transverse directions, but peripheral microtubuleswere always arranged only in a longitudinal direction. Thesefeatures were also noted in the cask-shaped cells. Colchicineat 10^–3M and 3?10^–3M accelerated both cell expansionand wall thickening with matrix deposition, but the directionsin which both microfibrils and microtubules were arranged werethe same as those of the cylindrical cells. These results indicatethat (1) the microfibril and microtubule arrangements of Chaetomorphaare not necessarily correlated, (2) changes in cell shape ofChaetomorpha are not necessarily accompanied by changes in thearrangement of cell-wall microfibrils, and (3) colchicine playsa role in the loosening and thickening of cell walls by enhancingmatrix deposition. (Received June 2, 1986; Accepted February 13, 1987)     

Self-immobilized recombinant Acetobacter xylinum for biotransformation

Biofilms have been successfully applied for biotransformation for decades, especially in the area of bioremediation due to the feature of harsh reaction condition resistance. Acetobacter xylinum is known for its cellulose pellicle forming capability. Like biofilm, A. xylinum cells are immobilized by simultaneously produced cellulose nanofibers in the pellicle. A recombinant A. xylinum was constructed with the expectation that the cells could be self-immobilized and achieve a desired and stable biotransformation. d-Amino acid oxidase (DAAO) of Rhodosporidium toruloides was used as the model enzyme to be expressed in the recombinant A. xylinum. The constructed recombinant A. xylinum not only successfully produced DAAO activity but also self-immobilized by cellulose nanofibers in both the static and shaken culture. Although self-immobilized cells demonstrated a DAAO activity approximately 10% of the cell crude extract activity, it provided the benefits of improved thermal stability, operational stability, and easy retrieval for repeated use.     

SYNTHESIS OF CELLULOSE BY ACETOBACTER XYLINUM : V. Ultrastructure of Polymer

Appearance of cellulose microfibrils in the medium of a suspension of cells of Acetobacter xylinum in buffered glucose solution was preceded by a stage during which the cellulose in the medium was amorphous within the available resolution. The size of the vertical axis of the microfibrils of the bacterial cellulose was found on the basis of measurement of shadow length to be only about 16 A. In good agreement with findings of earlier workers, the size of the lateral axis ("width") of the image of the metal-shadowed cellulose microfibrils was found to be 11 mµ. After correcting for a large part probably contributed by deposited metal in the observed width of the microfibrils, the real width is estimated roughly to be in the neighborhood of 3 mµ. To account for the occurrence of diverse morphological elements in the fields and for the fact that the cellulose fibrils are free entities rather than physical appendages of the cell, it is suggested that individual cellulose molecules are released at the cell surface and diffuse into the medium, wherein they finally enter into crystal-line patterns.     

Induction of orientation of bacterial cellulose microfibrils by a novel terpenoid from Acetobacter xylinum

1. The bacterium Acetobacter xylinum produces extracellular cellulose microfibrils that form a pellicle in the medium enmeshing the bacterial cells. These microfibrils may show some localized alignment, which can be seen as birefringence when the culture is viewed between crossed Polaroid sheets. 2. An increase in birefringence can be induced by the addition of small amounts of certain classes of lipids, particularly sterols, to the cultures. 3. A crude lipid extract from Acetobacter cells induced greatly increased birefringence when added to fresh cultures of this organism. 4. When the bacterial lipids were fractionated, most of the activity was recovered in a complex, polar lipid. The lipid is secreted into the medium during growth and is unstable. The non-saponifiable portion of this lipid is shown to be a 1:1 mixture of a saturated and a monounsaturated C₃₅ tetrahydroxy terpene with a hopane ring system in the accompanying paper by Förster et al. (1973). The saturated molecule is referred to as tetrahydroxybacteriohopane. 5. Tetrahydroxybacteriohopane is itself capable of inducing birefringence in cultures as is 22-hydroxyhopane, which was also isolated from the non-saponifiable fraction of the total lipids. 6. The mechanism of induction of birefringence (orientation of microfibrils) is not known. This is unlikely to be a specific effect, since all the above compounds are active (intact lipid, tetrahydroxybacteriohopane, 22-hydroxyhopane), as are other classes of lipid. It is suggested, however, that a common mechanism may be involved and that similar compounds may be concerned with control of microfibril alignment in the cells of higher plants.     

The Fine Structure of Bamboo Fibres: II. REFRACTIVE INDICES AND WALL DENSITY

In the fibres of Dendrocalamus strictus and D. longispathusit has been shown that the refractive indices of the outer walllamella, parallel and perpendicular to cell length, are correlatednot only with cell length but also with the density of the wholewall. The indications nevertheless are still that the variationin refractive indices with cell length are due mainly to changesin the orientation of the cellulose microfibrils. There is,however, a subsidiary effect of factors associated with density.These factors are briefly discussed     

Microfibrillar Structure, Cortical Microtubule Arrangement and the Effect of Amiprophos-methyl on Microfibril Orientation in the Thallus Cells of the Filamentous Green Alga, Chamaedoris orientalis

Microfibrillar structure, cortical microtubule orientation andthe effect of amiprophos-methyl (APM) on the arrangement ofthe most recently deposited cellulose microfibrils were investigatedin the marine filamentous green alga, Chamaedoris orientalis.The thallus cells of Chamaedoris showed typical tip growth.The orientation of microfibrils in the thick cell wall showedorderly change in longitudinal, transverse and oblique directionsin a polar dependent manner. Microtubules run parallel to thelongitudinally arranged microfibrils in the innermost layerof the wall but they are never parallel to either transverseor obliquely arranged microfibrils. The ordered change in microfibrilorientation is altered by the disruption of the microtubuleswith APM. The walls, deposited in the absence of the microtubules,showed typical helicoidal pattern. However, the original crossedpolylamellate pattern was restored by the removal of APM. Thissuggests that cortical microtubules in this alga do not controlthe direction of microfibril orientation but control the orderedchange of microfibril orientation. Amiprophos-methyl, Chamaedoris orientalis, coenocytic green alga, cortical microtubule, microfibrillar structure, tip growth     

The Net Orientation of Wall Microfibrils in the Outer Periclinal Epidermal Walls of Seedling Leaves of Wheat

Use of the dichroic stain chlor-zinc-iodine revealed that thenet orientation of cellulose wall microfibrils in the outerparadermal wall of the epidermis of seedling wheat leaves isprincipally transverse in the extension zone. The net orientationof microfibrils changes abruptly to principally longitudinalat the end of cell elongation. The net angle of orientationof microfibrils in the extension zone was not a function ofRht-dosage (number of dwarfing alleles), and neither leaf extensionrate nor estimated maximum relative elemental rate of elongationwere functions of microfibril orientation. The results indicatethat elongation rates are not regulated by the net angle oforientation of microfibrils and support the concept that leafextension rate is regulated by the length of the extension zone.Copyright1995, 1999 Academic Press Cellulose wall microfibrils, extension zone, elongation, Rht, wheat, Triticum aestivum L     

Ultrastructural studies on the cell walls in Fusarium sulphureum.

The cell walls of Fusarium sulphureum have a microfibrillar component that is randomly arranged. X-ray-diffraction diagrams of the microfibrils are consistent with a high degree of crystallinity and show that they are chitin. The chitin microfibrils of the peripheral walls envelop the hyphal apex and extend across the septae. During the first 8h in culture, the conversion of conidial cells to chlamydospores is evidenced by a swelling of the cells and the original microfibrils remain randomly arranged. Within 24h new wall material is deposited as the cells expand and the wall thickens. The new microfibrils are indistinguishable from those of the original conidial cells. After 3 days in culture, the chlamydospores are fully developed and have the characteristic thick wall which is a continuous layer of randomly arranged microfibrils. Chlamydospores maintained in a conversion medium for 8 days have microfibrils identical with those in 3-day-old cultures; thus a further change in the microfibril orientation did not occur during that period. Alkaline hydrolysis of the walls removes most of the electron-dense staining constituents from the inner wall layer and leaves the outer wall layer intact. This treatment also reveals some of the wall microfibrils. An additional treatment of the walls with HAc/H2O2 completely removes the wall components that react positively to heavy metal stains. The results are discussed in relation to the structure of other fungal cell walls.     

Changes in microfibril arrangement on the inner surface of the epidermal cell walls in the epicotyl of Vigna angularis ohwi et ohashi during cell growth

Throughout the entire period of cell growth, the microfibrils on the inner surface of the outer tangential walls of the epidermal cells of Vigna angularis epicotyls are running parallel to one another and their orientation differs from cell to cell. Although transverse, oblique and longitudinal microfibrils can be observed irrespective of cell age, the frequency distribution of microfibril orientation changes with age. In young cells, transversely oriented microfibrils predominate. In cells of medium age, which are still undergoing elongation, transverse, oblique and longitudinal microfibrils are present in quite similar frequencies. In old, non-growing cells, longitudinally oriented microfibrils are predominent. A decrease in the relative frequency of transversely oriented microfibrils with cell age was also observed in the radial epidermal walls.     

Orientation of Microtubules during Regeneration of Cell Wall in Selected Giant Marine Algae

The microtubules in highly synchronized aplanospores of twogiant marine algae, Boergesenia forbesii and Valonia ventricosa,were examined by immunofluorescence microscopy throughout theregeneration of the cell wall. Microtubule orientation was alwaysrandom up to 20 h after wounding, although the orientation ofcellulose microfibrils changed from random to parallel withinthat time period. When the rhizoid cells were in the stage ofelongation at 7 to 10 days after wounding, highly ordered microtubuleswere always observed along the longitudinal cell axis exceptat the very tip of the cells where random ones were found. Incontrast, the microfibrils in the innermost lamellae of newlysynthesized cell walls showed three different orientations,that is, transverse, longitudinal and oblique to the longitudinalcell axis. These observations suggest that microtubules maycontrol cell shape, but not the orientation of microfibrils.The mechanism of cell wall construction in these algae is discussedin relation to the self-assembly mechanism thought to operatein the construction of helicoidal cell walls. ³ Present address: Polymer Research Laboratory, Mitsui ToatsuChemicals, Inc., Yokohama, Kanagawa 244, Japan. (Received November 18, 1987; Accepted April 11, 1988)     

Localization of the Xyloglucan in Cell Walls in a Suspension Culture of Tobacco by Rapid-Freezing and Deep-Etching Techniques Coupled with Immunogold Labelling

Localization of xyloglucan in cell walls regenerated from tobaccoprotoplasts (Nicotiana tabacum L.; cv. BY-2) is visualized byrapid-freezing and deep-etching (RFDE) electron microscopy coupledwith immunogold electron microscopy. Xyloglucan was alreadydeposited in the cell wall 3 h after culture initiation. Xyloglucanwas mainly localized along microfibrils with a lesser amountin intersections between two crossed microfibrils in 120-hour-oldcells. These data support the previous hypothesis of Keegstraet al. (1973) that propose an interconnection between xyloglucanand cellulose. (Received May 22, 1998; Accepted July 13, 1998)     

Studies on Mature Seeds of Cuscuta pedicellata and C. campestris by Electron Microscopy

The seeds of Cuscuta pedicellata have been investigated by transmissionand scanning electron microscopy. Additional observations havebeen made on seeds of C. campestris by SEM only. The seed coatconsists of an outer single epidermis, two different palisadelayers, and an inner multiparenchyma layer. The outer epidermalwall in C. pedicellata has a thick cuticle and zones rich inpectic substances. The thicker ‘U-shaped’ cell wallsin the outer palisade layer are strengthened by a wall layerof hemicellulose. The inner palisade layer has thick walledcells with a ‘light line’. The inner cell wall ofthe compressed multiparenchyma layer has a thin cuticle. A fairlythick cuticle is positioned directly on the endosperm surface.The aleurone cell walls are different from the remaining endospermwalls. The latter are thick and believed to be of galactomannans.There is a ‘clear’ zone between the plasmalemmaand the cell wall in the aleurone cells. The embryo cells arepacked with lipids and proteins. In Cuscuta campestris mostendosperm has been absorbed during the seed development. Theembryo apex has two minute leaf primordia. The features of theCuscuta seeds are discussed in relation to functional and environmentalconditions. Cuscuta pedicellata, Cuscuta campestris, seed, seed coat, cuticle, cell walls, endosperm, aleurone cells, galactomannan, embryo, TEM, SEM     

Regulation of cell division in pea root tips after wounding: A possible role for ethylene

Summary Calcofluor White ST is a fluorescent brightener that has previously been shown to alter cellulose ribbon assembly in the bacteriumAcetobacter xylinum. In this report, we demonstrate that Calcofluor also disrupts cell wall assembly in the eukaryotic algaOocystis apiculata. When observed with polarization microscopy, walls altered by Calcofluor show reduced birefringence relative to controls. Electron microscopy has shown that these altered walls contain regions which consist primarily of amorphous material and which generally lack organized microfibrils. We propose that wall alteration occurs because Calcofluor binds with the glucan chains polymerized by the cellulose synthesizing enzymes as they are produced. As a consequence, the glucan chains are prevented from co-crystallizing to form microfibrils. Synthesis of normal walls resumes when Calcofluor is removed, which is consistent with our proposal that Calcofluor acts by direct physical interaction with newly synthesized wall components.Several types of fluorescent patterns at the cell wall/plasmalemma interface have also been observed following Calcofluor treatment. Fluorescent spots, striations; helical bands, and lens-shaped thickenings have been documented. Each of these patterns may be the result of the interaction of Calcofluor with cellulose at different spatial or temporal levels or from varying concentrations of the brightener itself. Helical bands and lens-shaped thickenings also have been examined with the electron microscope. Like other regions of wall alteration, they are found to contain primarily amorphous material. Finally, we note that cells with severely disrupted walls are unable to complete their normal life cycle.     

Cystolith Development and Structure in Pilea cadierei (Urticaceae)

Cystolith formation, structure and composition have been investigatedin leaves and stem internodes of Pilea cadierei (Urticaceae)using a variety of techniques at the light and electron microscopelevels. The development of lithocysts from epidermal cells hasbeen followed. These cells are cytoplasmically similar to otherepidermal cells but possess a much more active Golgi apparatusand more numerous mitochondria. The cystolith is a spindle-shapedbody composed of concentric layers of longitudinally orientatedcellulose microfibrils associated with pectins and other cellwall polysaccharides. At maturity it is heavily impregnatedwith calcium carbonate. Some cystoliths also contain siliconand are covered in a sheath of siliceous material. Cystolithformation occurs at the tip of a peg that grows in from thelithocyst wall. Evidence from ultrastructure suggests that thelithocytst cytoplasm transports carbohydrates to the cystolithvia Golgi vesicles, and organizes the deposition of cystolithcellulose microfibrils via a system of microtubules lying beneaththe plasma membrane that envelopes the growing cystolith. Thepeg is composed of heavily staining amorphous material likethat of an apoplastically sealed cell wall. It is incapableof supporting the migration of lanthanum ions into the cystolith.We conclude that cystoliths are isolated volumes of apoplastthat act as repositories for inorganic salts, principally calciumcarbonate. We propose that calcium ions move into the lithocystprotoplast from surrounding cells and are then transported acrossthe plasma membrane boundary into the cystolith. This proposalconflicts with previous suggestions that calcium enters by diffusionthrough the peg. Cystolith, lithocyst, cell wall, calcium, silicon, cytochemistry, electron probe analysis, Pilea cadierei     

Changes in Cell Wall Architecture of Differentiating Tracheids of Pinus thunbergii during Lignification

The cell wall architecture, before and after lignification,of differentiating tracheids in Pinus thunbergii has been examinedusing a rapid-freeze deep-etching technique combined with transmissionelectron microscopy. Replicas of cells from the cambial zoneshowed that the unlignified primary cell wall was highly porouswith microfibrils extensively interconnected by crosslinks.The unlignified secondary cell wall has unidirectional microfibrils,more or less associated in bundles, forming a wavy pattern aroundpores of characteristic slit-like shape with narrowing ends.As the lignification progresses, the cell wall structure becomesdense, with no detectable pores. Delignification of wood samplesleads to the reappearance of crosslinks, individual microfibrilsand pores in the secondary cell wall, although in a somewhataltered shape. In addition, cellulose-synthesizing enzyme complexes(rosettes) have for the first time been detected on the plasmamembrane of differentiating xylem cells of softwood. (Received August 28, 1998; Accepted March 10, 1999)     

Forced expression of FLO11 confers pellicle-forming ability and furfural tolerance on Saccharomyces cerevisiae in ethanol production

We constructed a plasmid that expresses FLO11 encoding a cell surface glycoprotein of Saccharomyces cerevisiae under the control of a constitutive promoter. This plasmid conferred pellicle-forming ability on the non-pellicle-forming industrial strain of S. cerevisiae at the air–liquid interface of the glucose-containing liquid medium. The induced pellicle-forming cells exhibited tolerance to furfural, which is a key toxin in lignocellulosic hydrolysates, in ethanol production.     

THE STRUCTURE OF THE PRIMARY EPIDERMAL CELL WALL OF AVENA COLEOPTILES

The primary walls of epidermal cells in Avena coleoptiles ranging in length from 2 to 40 mm. have been studied in the electron and polarizing microscopes and by the low-angle scattering of x-rays. The outer walls of these cells are composed of multiple layers of cellulose microfibrils oriented longitudinally; initially the number of layers is between 10 and 15 but this increases to about 25 in older tissue. Where epidermal cells touch, these multiple layers fuse gradually into a primary wall of the normal type between cells. In these radial walls, the microfibrils are oriented transversely. Possible mechanisms for the growth of the multilayered outer wall during cell elongation are discussed.