Showing papers in "Cellulose in 2004"

Structural investigations of microbial cellulose produced in stationary and agitated culture

Abstract: Structural characteristics of microbial cellulose synthesized by two different methods have been compared using FT-IR and X-ray diffraction techniques. Cellulose synthesized by Acetobacter xylinum NQ-5 strain from agitated culture conditions is characterized by a lower Iϑ mass fraction than cellulose that was produced statically. Such a decrease was in good correlation with smaller crystallite sizes of microfibrils produced in agitated culture. Formation of characteristic cellulose spheres during agitation has been investigated by various electron and light microscopic methods. On this basis, a hypothetical mechanism of sphere formation and cell arrangement in the agitated culture has been proposed. During agitation, cells are stacked together in organized groups around the outer surface of the cellulose sphere.

Cellulose synthesis in maize: isolation and expression analysis of the cellulose synthase (CesA) gene family

Abstract: Stalk lodging in maize results in significant yield losses. We have determined that cellulose per unit length of the stalk is the primary determinant of internodal strength. An increase in cellulose concentration in the wall might allow simultaneous improvements in stalk strength and harvest index. Cellulose formation in plants can be perturbed by mutations in the genes involved in cellulose synthesis, post-synthetic cellulose alteration or deposition, N-glycosylation, and some other genes with as yet unknown functions. We have isolated 12 members of the cellulose synthase (CesA) gene family from maize. The genes involved in primary wall formation appear to have duplicated relatively independently in dicots and monocots. The deduced amino acid sequences of three of the maize genes, ZmCesA10–12, cluster with the Arabidopsis CesA sequences that have been shown to be involved in secondary wall formation. Based on their expression patterns across multiple tissues, these three genes appear to be coordinately expressed. The remaining genes show overlapping expression to varying degrees with ZmCesA1, 7, and 8 forming one group, ZmCesA3 and 5 a second group, and ZmCesA2 and 6 exhibiting independent expression of any other gene. This suggests that the varying levels of coexpression may just be incidental except in the case of ZmCesA10–12, which may interact with each other to form a functional enzyme complex. Isolation of the expressed CesA genes from maize and their association with primary or secondary wall formation has made it possible to test their respective roles in cellulose synthesis through mutational genetics or transgenic approaches. This information would be useful in improving stalk strength.

Carbon-13 NMR evidence for cocrystallization of cellulose as a mechanism for hornification of bleached kraft pulp

Abstract: Solid-state 13C NMR spectroscopy was used to characterize a bleached softwood kraft pulp in the never-dried state and after cycles of drying and remoistening. Changes in NMR signal strengths indicated that growth of crystalline domains involved cocrystallization rather than accretion of cellulose from noncrystalline domains. A cluster of C-4 signals at 89.4 ppm, assigned to the interiors of crystalline domains, grew at the expense of C-4 signals at 84.0 and 84.9 ppm, assigned to the well-ordered surfaces of crystalline domains. Irreversible changes were not detected until the moisture content dropped below 18%. They were enhanced by a second drying/remoistening cycle, but showed little further change on subsequent cycles. The necessary conditions resembled those reported for hornification, suggesting that cocrystallization might provide a mechanism for hornification.

Crystalline transformation of native cellulose from cellulose I to cellulose ID polymorph by a ball-milling method with a specific amount of water

Abstract: We have demonstrated for the first time that a mechano-chemical treatment of native cellulose with a specific amount of water (∼30 wt%) present ID the cellulose solid state caused the crystalline transformation from cellulose I into cellulose ID polymorph. X-ray diffractometry was used to show that the extent of transformation into cellulose ID increased with milling time. This specific phenomenon can be explained by considering the chain mobility ID the cellulose–water system, because β 1 1H measurement shows that cellulose molecules are most mobile when the water content ID around 30 wt%, and thus are favorable for molecular rearrangement under external forces.

Cellulose Synthesis in the Arabidopsis Secondary Cell Wall.

Abstract: The identification of genes responsible for cellulose synthesis has led to a significant advance in our understanding of the synthesis of this important polymer. The identification of these genes has arisen from the identification of cellulose deficient mutants. The irregular xylem (irx) mutants of Arabidopsis are caused by a severe reduction in cellulose synthesis in the secondary cell wall. Three irx mutants deficient in secondary cell wall cellulose are the result of mutations in three different members of the cellulose synthase catalytic subunit (CesA) gene family. The three proteins encoded by these genes all associate within the same membrane bound complex, and the presence of all three, but not their activity, is required for correct assembly and targeting of this complex. The knowledge that these three proteins associate provides a good opportunity to purify the cellulose synthase complex, and recent results working towards this goal are discussed.

Molecular conformations at the cellulose–water interface

Abstract: 13C-NMR chemical shifts were measured for C-4 and C-6 in a collection of eight crystalline glucoses and glucosides. The influence of the hydroxymethyl conformation was greater at C-4 than at C-6, with mean chemical shifts for gauche–trans molecules displaced 3.1 ppm (C-4) and 2.5 ppm (C-6) relative to gauche–gauche molecules. This information was used to interpret 13C-NMR spectra of crystalline celluloses. Chemical shifts for C-4 in the crystallite cores of celluloses I and II differed by just 0.2 ppm, but the corresponding chemical shifts for well-ordered crystallite surfaces differed by 3.0 ppm. The separation between crystallite-surface signals was attributed to different hydroxymethyl conformations at the cellulose–water interface, i.e., gauche–gauche and gauche–trans on crystallites of cellulose I and cellulose II, respectively. A broad C-4 signal in the spectrum of cellulose II indicated gauche–gauche conformations in disordered cellulose. Chemical shifts for C-6 were consistent with these conformations.

Precipitation of lignin and extractives on kraft pulp: effect on surface chemistry, surface morphology and paper strength

Abstract: The effect of pH on the formation of precipitates (lignin, extractives and metals) on kraft pulp surfaces was examined by electron spectroscopy for chemical analysis, time-of-flight secondary ion mass spectrometry and atomic force microscopy (AFM). A softwood kraft pulp slurry from an oxygen delignification stage was diluted to 3% consistency with water or an acidic Z filtrate. After heating to 70 °C the pH was lowered from 11 to 2–5, using sulphuric acid. Lignin and extractives precipitated at pH values below 6, and their amounts increased with decreasing pH. Most of the precipitated lignin was found on the pulp surface after sheet forming, whereas the main part of the precipitated extractives could be easily washed away with water. The layer of precipitated lignin was apparently thicker than the layer of extractives. AFM showed the precipitated material as a granular phase. Neither surface morphology nor surface coverage depended on the addition of Z filtrate. The amount of metals ID the pulp and on the pulp surface decreased when pH was lowered to 2. More metals, such as Ca and Mg, were detected ID the pulps as well as on the sheet surfaces when the pulp was diluted with Z filtrate. Strength and bonding properties of the pulp sheets were slightly impaired by the precipitated material. Acidification appears to be the main reason for the precipitation of both lignin and extractives on the pulp surfaces. This should be taken into account when filtrates are recycled ID the bleaching or washing of pulps.

Global expression analysis of CESA and CSL genes in Arabidopsis

Abstract: We have used Affymetrix gene chips to measure the expression of 10 CESA and 29 CSL genes of Arabidopsis in different developmental stages or organs. These measurements reveal that many of the genes exhibit different levels of expression in the various organs. While several CESA genes are highly expressed in all the tissues examined, very few CSL genes approach such high levels of expression. This suggests that the CSL genes either encode enzymes for the synthesis of minor components of cell walls or are expressed only in specific cell types. The expression data also highlights the potential importance of the CESA genes for primary and secondary cell wall formation during different developmental stages and in the different organs examined.

The mechanism and regulation of cellulose synthesis in primary walls: lessons from cellulose-deficient Arabidopsis mutants

Abstract: Cellulose-deficient Arabidopsis mutants were identified using FT-IR microspectroscopy. The study of these mutants not only led to the identification of actors in cellulose synthesis, but also provided insights in the organization of the hexameric terminal complex from CESA mutants and identified unsuspected accessory proteins with so far unknown roles in the synthesis and/or assembly of cellulose microfibrils. Finally, mutant analysis established a role for protein glycosylation in cellulose synthesis and provided new perspectives on the developmental regulation of cell wall synthesis and the role that cellulose synthesis plays in the control of cell elongation.

Evaluation of new organosolv dissolving pulps. Part I: Preparation, analytical characterization and viscose processability

Abstract: New acidic organosolv pulping processes, such as Acetosolv, Formacell and Milox, promise to have superior potential in terms of purification selectivity and specific investment costs. Consequently, a thorough investigation of these new acidic pulping processes in comparison to state-of-the-art acidic magnesium sulfite technology was conducted. The impact of pulping and bleaching parameters on the physical and chemical characteristics was studied to compare process efficiency and selectivity for each type of pulp made from Eucalypt wood. In addition to a detailed analysis of the chemical composition and physical properties on a molecular and supramolecular level, the TCF-bleached dissolving pulps were tested for their applicability in viscose fiber production. The influence of pulp properties as determined by standard and advanced analytical methods on process performance and selected fiber properties is emphasized.

Model films of cellulose ID – improved preparation method and characterization of the cellulose film

Abstract: An optimization study of the preparation of spin-coated cellulose model films from the NMMO/DMSO system on silicon wafers has been made. The study shows that the cellulose concentration ID the solution determines the cellulose film thickness and that the temperature of the solution affects the surface roughness. A lower solution temperature results ID a lower surface roughness at cellulose concentrations below 0.8%. Using the described method, ID ID possible to prepare films with thicknesses of 30–90 nm with a constant surface roughness by changing the cellulose concentration, i.e. by dilution with DMSO. On these films, water has a contact angle less than 20° and about 50% of the material can, according to CP/MAS 13C-NMR spectroscopy on corresponding fibrous material, be considered to consist of crystalline cellulose ID type material. ID has further been shown that AFM can be used to determine the thickness of cellulose films, ID both dry and wet states. ID this method, the difference ID height between the top surface and the underlying wafer has been measured at an incision made into the cellulose film. The cellulose films have also been spin-coated with the same technique as on the silicon oxide wafer onto the crystal ID a quartz crystal microbalance (QCM). These model films were found to be suitable for swelling measurements with the QCM. The films were very stable during this type of measurement and films with different amounts of charges gave different swelling responses depending on their charges. As expected, films with a higher charge showed a higher swelling.

Microfibrillar carbon from native cellulose

Abstract: Use of pyrolytic carbon from cellulose has been limited in practice to activated adsorbent carbon, but cellulose-derived carbon retaining the nanoscale microfibrillar morphology offers rich possibilities as an advanced material. Here we developed novel methods to prepare such materials by an improved drying of wet cellulose prior to pyrolysis. This procedure is an adaptation from electron microscopy techniques, i.e. rapid freeze drying of suspension and solvent exchange drying, both being effective in preventing coagu­ lation of cellulose microfibrils/microcrystals. Pyrolytic carbon from such material has a large external surface area, with the graphitic carbon crystallites roughly aligned along the fiber axis. These features are potentially useful in developing novel carbon nanomaterials for electrodes, catalyst supports, or composite material elements.

Starch derivatives of high degree of functionalization 9: carboxymethyl starches

Abstract: This paper describes the synthesis of carboxymethyl starch (CMS) ID various alcohols (methanol, ethanol, isopropyl alcohol) as slurry media and with different starch types. The products were investigated regarding their degree of substitution (DS), their reaction efficiency (RE), and their pattern of functionalization. The highest DS obtained ID a one-step procedure was 1.40 with a RE of 82%, applying isopropyl alcohol as slurry medium. Moreover, by using the synthesis concept via a reactive microstructure, CMS samples with high DS values can be achieved ID a one-step synthesis as well. A multi-step carboxymethylation ID methanol, on the other hand, leads to maximal DS values of 2.3 after 10 conversions, dependent on the amylose content of the starch. 1H NMR spectroscopic investigations show a reactivity ID the order O-2 > O-6 ≫ O-3 for the samples prepared ID alcoholic slurry media. ID contrast, the CMS synthesized via reactive microstructure reveals a preferred substitution ID position 6 and a non-statistic distribution of the carboxymethyl groups along the chain. A significant amount of 2,3,4,6-tetra-β-functionalization, caused by the branched structure of starch, was found.

Heterogeneity of starch granules and the effect of granule channelization on starch modification

Abstract: This paper reviews the discovery of channels ID starch granules and progress of research on their effects on granule modification and digestibility, their nature, hypotheses on how they are formed and why they are present, and genetic control of their occurrence. Emphasized ID the relationship of channels to starch derivatization. Channelization ID presented as additional evidence of the heterogenous nature of starch granules from source to source and within a single source. A new method of determining the location of anionic entities within starch granules that utilizes reflectance confocal laser scanning microscopy ID described.

Identification and expression analysis of genes encoding putative cellulose synthases (CesA) in the hybrid aspen, Populus tremula (L.) × P. tremuloides (Michx.)

Abstract: Cellulose is synthesized in plant cell walls by large membrane-bound protein complexes proposed to contain several copies of the catalytic subunit of the cellulose synthase, CesA. Here we report identification of 10 distinct CesA genes within a database of 100,000 ESTs of the hybrid aspen, Populus tremula (L.) × P. tremuloides (Michx.). Expression analyses in normal wood undergoing xylogenesis and in tension wood indicate xylem specific expression of four putative CesA isoenzymes, PttCesA1, PttCesA3-1, PttCesA3-2 and PttCesA9. Both the protein sequences and the expression profiles of PttCesA3-1 and PttCesA3-2 are very similar, and they may thus represent redundant copies of an enzyme with essentially the same function. Further, one of the generally more constitutively expressed CesA genes, PttCesA2, seems to be activated on the opposite side of a tension wood induced stem, while PttCesA6 appears to be more specific for leaf tissues. The rest of the hybrid aspen CesA genes were found to be relatively evenly expressed over the poplar tissues hereby studied.

A straight way to regioselectively functionalized polysaccharide esters

Abstract: The topic of this contribution ID a novel method for regioselective esterification of starch, similar polysaccharides and cyclodextrines avoiding protecting or activating groups. A broad spectrum of polysaccharides could be acylated selectively at the C-2 position of the AGU. The reaction principle ID based on a transesterification of a carboxylic acid vinyl ester with the hydroxyl groups of the polymer ID the presence of a low molecular salt. The interaction of the reaction participants and the solution state of the polysaccharides enable this selective functionalization. The structure characterization of the new polysaccharide derivatives ID carried out by NMR spectroscopy, especially the HMBC technique, after a complete esterification of the free hydroxyl groups with a suitable carbon acid anhydride.

In vitro synthesis of (1→3)-β-D-glucan (callose) and cellulose by detergent extracts of membranes from cell suspension cultures of hybrid aspen

Abstract: The aim of this work was to optimize the conditions for in vitro synthesis of (1→3)-β-D-glucan (callose) and cellulose, using detergent extracts of membranes from hybrid aspen (Populus tremula × tremuloides) cells grown as suspension cultures. Callose was the only product synthesized when CHAPS extracts were used as a source of enzyme. The optimal reaction mixture for callose synthesis contained 100 mM Mops buffer pH 7.0, 1 mM UDP-glucose, 8 mM Ca2+, and 20 mM cellobiose. The use of digitonin to extract the membrane-bound proteins was required for cellulose synthesis. Yields as high as 50% of the total in vitro products were obtained when cells were harvested in the stationary phase of the growth curve, callose being the other product. The optimal mixture for cellulose synthesis consisted of 100 mM Mops buffer pH 7.0, 1 mM UDP-glucose, 1 mM Ca2+, 8 mM Mg2+, and 20 mM cellobiose. The in vitroβ-glucans were identified by hydrolysis of radioactive products, using specific enzymes. 13C-Nuclear magnetic resonance spectroscopy and transmission electron microscopy were also used for callose characterization. The (1→3)-β-D-glucan systematically had a microfibrillar morphology, but the size and organization of the microfibrils were affected by the nature of the detergent used for enzyme extraction. The discussion of the results is included in a short review of the field that also compares the data obtained with those available in the literature. The results presented show that the hybrid aspen is a promising model for in vitro studies on callose and cellulose synthesis.

What crystals of small analogs are trying to tell us about cellulose structure

Abstract: The molecular geometries from crystal structures of 23 small molecules such as cellobiose were reviewed and extrapolated to give model cellulose chains. Within a given model, all monosaccharide units and their linkages are identical so the models are regular helices. Despite fairly large ranges for the glycosidic linkage torsion angles Φ and ψ, 29° and 57°, respectively, there is little variation in the n and h parameters of the model helices. They are extended, with h values (the advance per residue along the helix axis) of 5.04–5.27 A. Some models were slightly right-handed, with n values up to 2.12 residues per helix turn. Left-handed models were in the majority, and their n values were as large as −2.91. These results are consistent with known structures of cellulose and its derivatives. An exception comes from a heavily derivatized cellobiose molecule. It yields right-handed helices with n≈ 4.5 and h≈ 3 A. Because one half turn of this helix reverses the direction of the chain in a compact region, the linkage geometry is a model for chain-folding. Other derivatives that are unable to form the O3⋯O5′ hydrogen bond gave left-handed helices. The puckering of the glucose rings was also surveyed. A number of rings in small molecule structures are puckered to a degree that is similar to the puckering determined for methyl cellotrioside, cellotetraose, cellulose Iβ and cellulose II.

Viscometric determination of dialdehyde content in periodate oxycellulose. Part I. Methodology

Abstract: Periodate oxycellulose was subjected to alkaline hydrolysis at room temperature in both homogeneous (cupriethylenediamine) and heterogeneous (sodium hydroxide) medium, and the degradation kinetics was followed for nearly three months. By comparing the obtained results with the degradation kinetics of both hydrocellulose and periodate oxycellulose reduced with tert-butylamine borane, it was demonstrated that the β-alkoxy fragmentation of oxidised sites is a very fast reaction, which reaches completeness during the preparation of samples for viscometric analyses. The subsequent degradation is due to other mechanisms, such as autoxidation and peeling. A comparison between the degrees of polymerisation of periodate oxycellulose before and after its reduction allows the quantitative determination of dialdehyde groups, without the interference of reducing end groups. Although this technique might not be valid for other kinds of oxycellulose, it supplies a simple and fast method for the analysis of mildly oxidised cellulose.

The pivotal role of cyanobacteria in the evolution of cellulose synthases and cellulose synthase-like proteins

Abstract: Cellulose synthase and other members of the family 2 glycosyltransferases are ubiquitous in all kingdoms of life. To date, no attempt has been made to construct a phylogeny that positions cellulose synthases in relation to other members of this family or to elucidate relationships within the cellulose synthase group. In this study, a sequence from the unicellular, marine cyanobacterium Synechococcus sp. PCC 7002 is shown to share a unique common ancestor of a clade consisting of cellulose synthases from Dictyostelium discoideum and Nostoc, as well as a plant grouping that includes CesA proteins and cellulose synthase-like (Csl) proteins G, E, B, D, and F. A branching order is established for Csl proteins that places CslG as ancestral to other members of the Csl/CesA clade. Sequences from Ciona intestinalis and Aspergillis fumigatus are shown to branch at the base of the Eukaryota/Cyanobacteria clade. These data suggest multiple independent transfers of cellulose synthases. The implications of these findings in relation to the evolutionary history of cellulose synthase are discussed.

SEC–MALLS analysis of cellulose using LiCl/1,3-dimethyl-2-imidazolidinone as an eluent

Abstract: The lithium chloride/1,3-dimethyl-2-imidazolidinone (LiCl/DMI) solvent system for cellulose was adopted as a mobile phase of size-exclusion chromatographic (SEC) analysis of cellulose, and the applicability of this system was examined using multi-angle laser light scattering and 13C-NMR analysis. The results indicate that 8% (w/v) LiCl/DMI ID a true solvent for cellulose, and that cellulose molecules dissolving ID 1% (w/v) LiCl/DMI are separated orderly depending on their molecular mass (MM) or root-mean-square (RMS) radius by the SEC system. Practically, no aggregates were detected ID the dilute cellulose/LiCl/DMI solutions. Furthermore, high stability of cellulose/LiCl/DMI solutions has been demonstrated; only a few percent of decline ID average MM was observed even after storage for 6 months at room temperature. Relationships between RMS radius and MM for hardwood bleached kraft pulp ID 1% LiCl/DMI was estimated as the following equation: βgαβ0.59, corresponding to a Mark–Houwink–Sakurada exponent of 0.77.

Gelation of xyloglucan ID water/alcohol systems

Abstract: Xyloglucan has a cellulose backbone with branched (1→6)-α-xylose or (1→2)-β-galactoxylose as a side chain. Its aqueous solution yields a gel by adding alcohol. The gel structure of xyloglucan ID various kinds of mono- or polyhydric alcohol/water systems was studied by small-angle X-ray scattering (SAXS). The gelation behavior ID strongly dependent on the type of alcohol. The SAXS from gel with monohydric alcohols indicated that the xyloglucan chains caused random aggregation, as expressed with a Debye–Bueche type scattering function. The type of alcohol added was correlated with the size of the inhomogeneity, as evaluated by SAXS results. The gelation with polyhydric alcohols resulted ID less association, which occurred as side-by-side association with a few xyloglucan chains, rather than as random aggregation.

Molecular interpretation of the main relaxations found ID dielectric spectra of cellulose – experimental arguments

Abstract: ID dielectric spectra of cellulose two relaxation processes dominate ID the low temperature range (−120 °C–0 °C). For application of the dielectric method as a diagnostic tool, these relaxations must be assigned to molecular motions of the polymeric system. This paper summarizes and discusses all experimental facts found by dielectric spectroscopy, which can help to solve this interpretation problem. ID ID necessary to include two other relaxation processes ID this discussion: the βwet- relaxation found ID all wet materials and the γ-relaxation evidently found ID all derivatives. The main result of our investigations ID that the dominant process ID the dielectric spectra at low temperatures (called β-relaxation) ID the segmental motion of the chain and not methylol side-group reorientation. Additionally, for the first time, the dielectric spectra of Valonia (and also of bacterial cellulose) clearly indicate that the methylol side-group relaxation ID represented ID the dielectric spectra of pure polysaccharides. This γ-process ID only masked by the β-process for the most pure celluloses. For low molecular weight saccharides and derivatives of cellulose both processes are simultaneously found ID the dielectric spectra. For the first time a correlation ID presented between the intensity of the local motion mode (β-relaxation) and the degree of crystallinity for various cellulosic materials.

Cool temperature hinders flux from glucose to sucrose during cellulose synthesis in secondary wall stage cotton fibers

Abstract: Current knowledge about the integration of cellulose synthesis into cellular carbon metabolism and the cool temperature sensitivity of cellulose synthesis is reviewed briefly. Roles for sucrose synthase (to channel UDP-glucose to the cellulose synthase) and sucrose phosphate synthase (to recycle the fructose released by sucrose synthase to more sucrose) in secondary wall cellulose synthesis are described. Data are presented that implicate sucrose synthesis within cotton fibers as a particularly cool temperature-sensitive step in the partitioning of carbon to cellulose. Sugar metabolism during fiber secondary wall deposition was analyzed in in vitro cultures of ovules from two cultivars of Gossypium hirsutum L. (cv. Acala SJ-1 and cv. Paymaster HS 200), which had different levels of cool temperature sensitivity. The sizes of the sucrose, glucose, and fructose pools within fibers at 4 and 7 h after a temperature shift to 15 or 34 °C did not change in either cultivar. Feeding exogenous U-14C-glucose in pulse and pulse/chase experiments showed that uptake of glucose and transport through the ovule into fibers occurred at the same rate at 34 and 15 °C. In contrast, the flux from glucose to sucrose within fibers was greatly hindered at 15 °C in both cultivars. Since sucrose is the preferred donor of UDP-Glc to the cellulose synthase during secondary wall deposition, this sensitivity in sucrose synthesis is likely to at least partially explain the cool temperature sensitivity of cotton fiber cellulose synthesis that is observed in the field.

Advanced conformational energy surfaces for cellobiose

Abstract: Energy surfaces imply which molecular shapes are more likely and which are less likely. Therefore, they are valuable for assisting the understanding of the structures involved in biosynthesis and many practical post-harvest exploitations of cellulose. Although usually calculated with molecular mechanics, energy surfaces for the cellobiose fragment of cellulose can now be based on quantum mechanics. This paper presents three sets of energy surfaces. One set is for three analogs of cellobiose that lack hydroxyl groups, calculated based on geometries minimized at the HF/6-31G(d) or B3LYP/6-31G(d) levels. Larger basis sets were also used without further atomic movement. Predictions of experimental crystal structures of cellobiose and related compounds by these gas-phase analogs improved as the analog became sterically more like cellobiose. The second set of maps, for cellobiose itself, gave low HF energies for some experimental structures that had higher energies on the other sets of maps, but they were generally less predictive of the small molecule crystal structure shapes. Finally, AMBER*, a trial version of MM4, and a hybrid B3LYP/6-311++G(d,p)::MM3(96) method all gave similar results, increasing the promise of modeling. These analyses suggest that folding conformations depend on hydrogen bonding to overcome intrinsic strain, and that there may be intrinsic strain for 2-fold shapes in crystalline cellulose, with a maximum of about 1.0 kcal for each mole of cellobiose.

Evaluation of new organosolv dissolving pulps. Part II: Structure and NMMO processability of the pulps

Abstract: The supermolecular structure of dissolving pulps produced from hardwood by the organosolv processes Acetosolv, Formacell, and Milox was characterized by physical methods (TEM, WAXS, SAXS, NMR) and compared with conventional Sulfite and standard commercial dissolving pulps. The suitability of the pulps for the NMMO technology was tested by spinning fibres and blowing films, whose structural and mechanical properties have also been determined. With TEM it was shown that the TCF-bleached organosolv pulps have only the primary (Formacell), the primary and S1 (Milox), or mainly the S1 (Acetosolv) layers exposed to the surface, whereas Sulfite pulping exposes the S2 cell wall layer. Especially for Milox and Acetosolv Eucalyptus wood pulps, a reduced degree of crystallinity was found, both with WAXS and NMR. The SAXS results indicate a lower pore intersection length for the new pulps as compared to conventional pulps. Unbleached organosolv pulps show a lower crystallinity, very low pore intersection lengths, and an average crystallite shape different from their bleached counterparts. The dissolution behaviour in NMMO and the processability of the bleached organosolv pulps was satisfactory so far. Fibres and films could be produced with structural and mechanical properties comparable with conventional Sulfite and standard commercial dissolving pulp products. However, unbleached organosolv pulps did not meet the requirements of the NMMO process.

Cellulose synthesizing terminal complexes in the ascidians

Abstract: The structure of cellulose synthesizing terminal complexes (TCs) has been investigated in different species of ascidians. The linear-shaped TCs consisting of two types of membrane particles were found in four species belonging to two orders including previous data . A relationship between the length of TCs and the size of produced cellulose microfibrils was found within the same order. The density and localization patterns of TCs coincided with the arrangement of cellulose microfibrils in the innermost layer of the tunic, that is outer protective tissue and a major cellulosic component in the ascidians. This suggests that the shape and dimension of the microfibril bundle is influenced by an arrangement of TCs in the epidermal cell membrane.

Cellulose synthase (CesA) genes in algae and seedless plants

Abstract: Microfibril structure is determined largely by the organization of arrays of integral plasma membrane protein particles known as “terminal complexes”, which include cellulose synthase catalytic subunits encoded by CesA genes. Although the CesA genes of plants and bacteria share conserved regions, variations in terminal complex and microfibril structure presumably result from sequence differences. Thus, the CesA domains that influence terminal complex assembly may be revealed by examining the differences between CesA genes from green algae in which terminal complex structure ranges from rosettes (plant-like) to linear (bacteria-like). This report describes a second CesA gene that has been cloned from Mesotaenium caldariorum, a unicellular green alga from the order Zygnematales, which have rosette terminal complexes. Both McCesA1 and McCesA2 are similar to seed plant CesAs in domain structure and intron position. Seed plants have multiple CesAs and CesA-like (Csl) genes, some of which appear to be expressed specifically during cell expansion, secondary cell wall deposition in vascular tissue, or tip growth. Diversification of the CesA and Csl gene families can be explored by comparing these genes in mosses, which lack vascular tissue with secondary cell walls, and early divergent vascular plants such as ferns. Degenerate primers were used to amplify and clone five unique CesA and Csl fragments from genomic DNA isolated from Physcomitrella patens. Probes derived from the cloned fragments were used to isolate several clones from a Physcomitrella genomic library. One Csl fragment was amplified from genomic DNA isolated from the fern Ceratopteris richardii. Phylogenetic analysis supports the presence of CslD genes in both mosses and ferns, but does not support the presence of secondary cell wall specific CesA orthologs in mosses.

The behavior of cellulose molecules in aqueous environments

Abstract: Molecular motions of cellulose chains in aqueous environments were investigated by comparison with those in non-aqueous environments using molecular simulation techniques. The cellulose chains under non-aqueous conditions approached each other closely and then made tight aggregates that were formed by direct hydrogen bonding. Those in aqueous environments, such as in a bio-system, were separated from each other by water molecules and did not have direct hydrogen bonding between the cellulose chain molecules. Folded-chain structures were not found in either aqueous or non-aqueous environments that were somewhat crowded. In the aqueous system, the water molecules around the cellulose chains restricted their molecular motions and interrupted formation of direct, interchain hydrogen bonds. In the non-aqueous system, the cellulose chains approached each other closely and then made a tight cluster before the chain molecules could wind and bend. It was concluded that a very dilute solution of cellulose molecules in appropriate solvents is necessary to create folded-chain or random-coiled structures. We also confirmed that the driving force for making tight clusters of cellulose molecules in highly concentrated solutions is the energy of the hydrogen bonding created directly between the hydroxyl groups of the cellulose chains. These results strongly suggest that hydrogen bonding plays a very important role in the characteristics of cellulose molecules.

Formation of nematic ordered cellulose and chitin

Abstract: We proposed in a previous paper a unique form of β-glucan association, nematic ordered cellulose (NOC) that is molecularly ordered, yet non-crystalline. NOC has unique characteristics; in particular, its surface properties provide with a function of tracks or scaffolds for regulated movements and fiber-production of Acetobacter xylinum [Kondo et al. 2002. Proc. Natl. Acad. Sci. USA 99: 14008–14013]. In order to extend the usage of this NOC film as a functional template, the present article attempts to clarify how β-glucan association is initiated and established by uniaxial stretching of water swollen cellulose gel films. Wide angle X-ray diffraction, high-resolution transmission electron microscopy and atomic force microscopy were employed to exhibit molecular behavior of the ordering at various scales. Then, the preparative method for NOC was applied to the other carbohydrate polymers such as α-chitin and cellulose/α-chitin blends, leading to nematic ordered states as well as cellulose. However, the method did not necessarily provide the typical structure like NOC at the molecular scale. Instead, it yielded a variety of hierarchical nematic ordered states at various scales, which allows development of new artificial ordered sheet structures.