GROWTH AND WOOD PROPERTIES OF GMELINA ARBOREA (VERBENACEAE) SEEDLINGS GROWN UNDER FIVE SOIL MOISTURE REGIMES

The effects of different watering regimes on vegetative growth, histological properties of wood, and the derived values relevant to paper and pulp production of Gmelina arborea Roxb. were investigated. Soil moisture stress significantly retarded vegetative growth as analyzed by leaf area ratio, root shoot ratio, net assimilation rate, and relative growth rate. Moisture stress also adversely affected specific gravity of the wood, fiber length, diameter, lumen size, and fiber wall thickness, but enhanced flexibility coefficient, lowered slenderness ratio, and runkel ratio. Although water stress reduces the volume of wood produced and changes wood fiber properties, it does not significantly affect the quality of paper produced from Gmelina wood.     

Prior secondary cell wall formation is required for gelatinous layer deposition and posture control in gravi-stimulated aspen

Cell walls, especially secondary cell walls (SCWs), maintain cell shape and reinforce wood, but their structure and shape can be altered in response to gravity. In hardwood trees, tension wood is formed along the upper side of a bending stem and contains wood fiber cells that have a gelatinous layer (G-layer) inside the SCW. In a previous study, we generated nst/snd quadruple-knockout aspens (Populus tremula × Populus tremuloides), in which SCW formation was impaired in 99% of the wood fiber cells. In the present study, we produced nst/snd triple-knockout aspens, in which a large number of wood fibers had thinner SCWs than the wild type (WT) and some had no SCW. Because SCW layers are always formed prior to G-layer deposition, the nst/snd mutants raise interesting questions of whether the mutants can form G-layers without SCW and whether they can control their postures in response to changes in gravitational direction. The nst/snd mutants and the WT plants showed growth eccentricity and vessel frequency reduction when grown on an incline, but the triple mutants recovered their upright growth only slightly, and the quadruple mutants were unable to maintain their postures. The mutants clearly showed that the G-layers were formed in SCW-containing wood fibers but not in those lacking the SCW. Our results indicate that SCWs are essential for G-layer formation and posture control. Furthermore, each wood fiber cell may be able to recognize its cell wall developmental stage to initiate the formation of the G-layer as a response to gravistimulation.     

Wood specific gravity and anatomy in Heliocarpus appendiculatus (Tiliaceae)

Specific gravity exhibits extremely large radial increases with distance from the pith in Heliocarpus appendiculatus Turcz. (Tiliaceae), a pioneer of neotropical wet forests. To determine some of the wood anatomical changes associated with this increase, wood samples taken at breast height from three trees were divided into 1.0-cm-long segments from pith to bark. Measurements were made of fiber wall thickness, fiber lumen diameter, and percentages of fibers, axial parenchyma, ray parenchyma, and vessels on sections prepared from each segment. The extreme radial increases in specific gravity were associated with increases in fiber wall thickness, decreases in fiber diameter, decreases in fiber lumen diameter, and changes in the relative proportions of fibers and parenchyma. The increase in percent fiber concomitant with a decrease in axial parenchyma was the most important contributor to the increase in specific gravity in this species. The best predictor of specific gravity was percent fibers (r = 0.91, 0.92, 0.94) or percent axial parenchyma (r = -0.92, -0.91, -0.95), two variables that were highly intercorrelated (r = -0.95, -0.98, -0.99).     

Microbial-assisted remediation of creosote- and pentachlorophenol-treated wood products

A recycling process designed to recover wood fiber from discarded utility poles and cross ties was tested. Laboratory and field studies were conducted using a combined physical, chemical and microbiological protocol designed for the removal of creosote and pentachlorophenol wood preservatives from wood fiber. Woodchips produced in an industrial type wood chipper were batch extracted in methanol. The extractions successfully removed more than 95% of eight major creosote compounds contained within the woodchips. An initial combined concentration of 29 262 ppm during the extraction phase was reduced to 95 ppm in the laboratory study and to 1364 ppm in the field study. Biopolishing with a microbial consortium containing adapted strains from the generaPseudomonas, Flavobacterium andAcinetobacter further reduced the preservative concentration to 8 ppm and 200 ppm, respectively, with anthracene being the most recalcitrant compound in both studies. Pentachlorophenol-treated wood with an initial concentration of 1190 ppm, when subjected to the recycling process, yielded end product wood containing less than 2 ppm of the preservative. The solvent/preservative mixture (miscella) produced during the extraction process yielded a pure methanol fraction and a still bottom mixture when subjected to flash distillation. Fractional (vacuum) distillation of the still bottom mixture produced methanol, creosote, pentachlorophenol, and coal tar fractions.     

Introduction and verification of a novel method for measuring wood fiber length using a single cross section in Acacia mangium

A novel method for calculating the wood fiber length using a single cross section was devised and verified in Acacia mangium. This method is based on the ratio of cell tips to total cell number in a cross section related to the wood fiber. The fiber length was calculated using the single cross-section method and was compared with the measurements obtained using the conventional maceration method and the serial cross-section method. There was no significant difference among the three methods.     

First record of Cercidiphylloxylon (Cercidiphyllaceae) from the Palaeocene of Fushun,NE China

Abstract Cercidiphylloxylon spenceri (Brett) Pearson is described from the Lizigou Formation, Palaeocene in China. The growth rings are distinct; pores are diffuse, solitary, with somewhat angular outlines in cross section; vessel elements long with long scalariform perforation plates; intervessel pitting is opposite to scalariform; fiber‐tracheids are present; axial parenchyma is scarce; rays are mostly biseriate and heterogeneous. All wood characters of the fossil specimen fall into the range of those of extant Cercidiphyllum (Cercidiphyllaceae). The finding is one of the earliest fossil wood records of Cercidiphyllaceae.     

Plant fibers: Initiation,growth, model plants,and open questions

Fibers, which are used as a major raw material in the paper industry, as structural components in timber for building, and in the manufacture of wooden items, are among the most important renewable resources. Billions use wood as a major energy source, and fibers are an energy-rich component of wood. They are used for various textiles and as raw material for composites. In this review, I describe the basic characters of fibers, their structure, development, uses, and some of the current major model plants for fiber formation. I discuss open developmental questions and various aspects of further research. Most of the recent progress in the biology of fiber formation, especially in their cell-wall chemistry, emerged from studies of several model plants: Arabidopsis thaliana, Populus sp., Eucalyptus sp., flax, and hemp. I stress the critical need to combine the use of modern methods of research with classical botany. Approaching the issue of fiber formation only by molecular or only by classical methods will not only limit the progress, but may result in critical mistakes. Considering the importance of fibers to humanity, it is surprising how little we know about the biology of fiber formation and how little it is studied as compared, for instance, to the effort to study the genetics and cell biology of flower organ identity.     

The Inflorescence Stem Fibers of <Emphasis Type="Italic">Arabidopsis thaliana Revoluta</Emphasis> (<Emphasis Type="Italic">ifl1</Emphasis>) Mutant

Arabidopsis thaliana is gradually gaining significance as a model for wood and fiber formation.revolute/ifl1 is an important mutant in this respect. To better characterize the fiber system of therevolute/ifl1 mutant, we grew plants of two alleles (rev-9 in Israel andrev-1 in the USA) and examined the fiber system of the inflorescence stems using both brightfield and polarized light. Microscopic examination of sections of plants belonging to the two different alleles clearly revealed that, contrary to previous views, in 18 (13 in Israel and 5 in Ohio) out of 30 stems (20 in Israel and 10 in Ohio) the mutant produced the primary wavy fiber system of the inflorescence stems. Our findings are further supported by the fact that fibers are seen in the figures published in other studies of the mutant even when it was stated that there were no fibers. The impression of a total lack of the wavy band of fibers is in many cases just a result of poorly lignified secondary walls. This specific gene that reduces lignification in fibers is of great significance for biotechnological developments for the paper industry and thus for the global economy and ecology. We propose thatrevoluta, the first name given to this mutant (Talbert and others 1995), is more appropriate thanifl1. Online publication: 7 April 2005     

Ciclo di Accrescimento E Differenziazione Delle Gemme in Piante Perenni Nel Territorio di Bari

Summary

Growth cycle and buds differentiation in perennial plants growing in Bari's area. — V. The evolution of the wood ring in Rhammus Alaternus L. from December 1946 to March 1949.

In Rhamnus Alaternus L. the cambium awackens in March with the production of an early wood, characterized by large vessels and loose fibers. It keeps on dividing the following months, producing intermediary wood, whose vessels become narrower and narrower. In June the wood ring is almost complete and the cambial activity slows down. In July late wood is formed, with narrow tracheae and highly lignified fibers. From August to February cambial activity is very scarce and irregular, in the wood produced fibers being tangentially compressed.

In a young branch of R. A. cambium becomes suddenly active in February, that is one month before than in the stem, it goes on during the month of March-June, with an evident diminution in the size of the wood elements. This diminution of size instead of being regular, shows some oscillations, expecially during the month of May. In Sept. the cambium starts again dividing, but rather poorly and irregularly, forming some vessels a little wider than the preceeding ones, so that an incomplete false ring is formed only in some points of the branch. As a rule the autumn wood is a typical late wood. This scarce and irregular cambial activity goes on also during Oct.-Dec. In January is more active and forms rather wide vessels in comparison with those formed in the preceeding month. This new formed wood however does not show the characteristics of the early wood of a new ring.

Concluding, the characteristics of the cambial activity of A. R. are

In the stem: 1) March: early wood. 2) March-June: intermediary wood. 3) July: late wood, resting period. 4) At the end of Autumn a scarce production of late wood is sometimes possible.

In the young branch: 1) February: early wood. 2) March-June: intermediary wood, with positive and negative oscillations in the vessels width. 3) At the end of June the late wood is already differentiated. 4) July-August: resting period. 5) Spt.-Juan.: the cambium starts again dividing very scarcely and producing a transition wood between the two rings. This wood can be regarded neither as a true ring nor a false one, it represents rather the last phase of the late wood formation. 6) In the young branch of the female specimen the cambium starts dividing somewhat later than in the male one. 7) The wood ring width does not vary much in relation to the yearly amount of rainfall. The lack of relation between rainfall and ring width is particularly evident in 1948 (a rainy year). The, «Compleasance» of R. A. could show that this species is, in Puglia, in its own habitat. On the other hand it is rather peculiar that R. A. forms only one wood ring during one year, with production of early wood during the spring, and of late wood in the autumn, instead of producing a second autumn ring following a distint summer rest, as could be expected.     

Removal of CCA from treated wood by oxalic acid extraction, steam explosion, and bacterial fermentation

Most preservative-treated wood produced and consumed in the United States is treated with toxic inorganic compounds containing copper, chromium, and arsenic. Because chromated copper arsenate (CCA) is fixed to the wood, CCA-treated wood has not been considered toxic or hazardous and it is currently disposed of in approved landfills. Growing public concern about environmental contamination from treated wood combined with the removal of greater quantities of CCA-treated wood from service have presented a disposal challenge for this fiber source. In this study, CCA-treated wood was processed by acid extraction, steam explosion, and bacterial fermentation and evaluated for removal of copper, chromium, and arsenic. Copper was the easiest to remove by these treatments and chromium the most resistant to removal. Exposing CCA-treated wood to steady-state bacterial growth by continuous culture with Bacillus licheniformis CC01 did not enhance removal of CCA components compared to standard mixed culture when acid extraction preceded bacterial fermentation. Nor did steam explosion, alone or in conjunction with acid extraction and bacterial fermentation, enhance removal of CCA components; the chromium and arsenic components resisted removal. Grinding CCA-treated wood chips into 20-mesh sawdust provided greater access to and removal of CCA components by all processes. However, grinding the chips was unnecessary if they were treated with acid prior to bacterial fermentation. Extraction with oxalic acid as a precursor to bacterial fermentation with B. licheniformis CC01 removed 90% copper (CuO), 80% chromium (CrO₃), and 100% arsenic (As₂O₅) from treated chips. The combination of acid extraction and bacterial fermentation removed 80–100% of these metals from CCA-treated wood. Received 15 December 1997/ Accepted in revised form 08 March 1998     

Chemical composition and potential for utilization of the marine alga Rhizoclonium sp.

This paper reports on the feasibility of utilizing the abundant marine alga Rhizoclonium as a substitute for wood fiber, based on studies on its morphology and chemical composition. The alga appears as wood fiber-like filaments consisting of tubular end-to-end connections of individual cells. In the population studied, each cell averaged 82 μm long, 76 μm wide and had cell wall 7.4 μm thick. The composition was 15.9% ash, 9.72% extractable by 90% acetone, 9.43% extractable by alcohol-benzene, 3.8% acid insoluble fraction, 17.8% pentosan, 36.3% 1% NaOH soluble fraction and 57.4% carbohydrate. The composition of its carbohydrates is similar to that of wood fiber. After hydrolysis, reduction, and acetylation of the sugars, and GC-MS analysis the components showed glucose (65.8%), xylose (19.8%), galactose (12.5%) and mannose (1.3%). There were high contents of cold- and hot-water extractables, 31.1% and 34.6%, respectively. These consisted of xylose, galactose and glucose. The crystallinity index (CI%) of its holocellulose was as high as 86.5%, close to the 90.5% value of wood fiber. The 1091 cm^-1 peak intensity increased with reaction cycles, suggesting decreasing absorptivity and increasing crystallinity. This corresponds to terrestrial plant fibers. Taken together, these features suggest that Rhizoclonium has good potential as a raw material for pulp. This revised version was published online in August 2006 with corrections to the Cover Date.     

Gut microbiomes of sympatric Amazonian wood‐eating catfishes (Loricariidae) reflect host identity and little role in wood digestion

Neotropical wood‐eating catfishes (family Loricariidae) can occur in diverse assemblages with multiple genera and species feeding on the same woody detritus. As such, they present an intriguing system in which to examine the influence of host species identity on the vertebrate gut microbiome as well as to determine the potential role of gut bacteria in wood digestion. We characterized the gut microbiome of two co‐occurring catfish genera and four species: Panaqolus albomaculatus, Panaqolus gnomus, Panaqolus nocturnus, and Panaque bathyphilus, as well as that of submerged wood on which they feed. The gut bacterial community did not significantly vary across three gut regions (proximal, mid, distal) for any catfish species, although interspecific variation in the gut microbiome was significant, with magnitude of interspecific difference generally reflecting host phylogenetic proximity. Further, the gut microbiome of each species was significantly different to that present on the submerged wood. Inferring the genomic potential of the gut microbiome revealed that the majority of wood digesting pathways were at best equivalent to and more often depleted or nonexistent within the catfish gut compared to the submerged wood, suggesting a minimal role for the gut microbiome in wood digestion. Rather, these fishes are more likely reliant on fiber degradation performed by microbes in the environment, with their gut microbiome determined more by host identity and phylogenetic history.     

Genetic effects on wood quality traits of plantation-grown white spruce (Picea glauca) and their relationships with growth

Clonal repeatabilities on individual tree (H_i² H_i^2 ) and clonal mean (H_{[`(C)]</sub> <sup>2</sup> H_{{\overline C }}^2 ) bases for growth (14-year height and volume), wood quality traits (latewood proportion, wood density, fiber length, and microfibril angle), and genotypic correlations among the traits were estimated, using 30 white spruce (Picea glauca [Moench] Voss) clones from six full-sib families (five per family). These families were selected from a clonally replicated test to represent different early growth categories: fast, moderate, and slow. Wood increment cores of the 30 clones were collected from two contrasting sites at age 19 years. For growth traits, in contrast to most wood quality traits, more genetic variation was accounted for by clone within family than by family within growth category. Both growth and wood quality traits appear to be under moderate genetic control, with [^(H)]<sub>i</sub><sup>2</sup> = 0.20 - 0.36 \widehat{H}_i^2 = 0.20 - 0.36 and [^(H)]<sub>[`(C)]} ² = 0.70 - 0.83 \widehat{H}_{{\overline C }}^2 = 0.70 - 0.83 . The only exception was microfibril angle ( [^(H)]_i² = 0.10  \textand  [^(H)]_[`(C)] ² = 0.34 \widehat{H}_i^2 = 0.10\;{\text{and}}\;\widehat{H}_{{\overline C }}^2 = 0.34 ). Generally, faster growth resulted in a significantly lower latewood proportion and lower overall wood density. Selection for faster growth does not appear to impact on either fiber length or microfibril angle. Among the wood quality traits, significant genotypic association was observed only between latewood proportion and wood density. Despite the generally negative association between growth and wood density among families, several fast-growing clones maintained above-average density. This implies that, by adopting multiclonal forestry, one can simultaneously improve growth and wood density.     

Identification and quantification of radical reaction intermediates by electron spin resonance spectrometry of laccase-catalyzed oxidation of wood fibers from beech (Fagus sylvatica)

During laccase-catalyzed oxidation of beech wood fibers in an aqueous suspension, phenoxy radicals were detected in steady-state concentrations by electron-spin resonance (ESR) spectrometry of the suspension liquid, suggesting that colloidal lignin functions as a mediator between laccase and the fiber lignin matrix. Phenoxy radicals were observed directly, whereas ESR spin-trapping techniques gave no evidence for reduced oxygen species, such as the superoxide or hydroxyl radical. A reaction mechanism involving parallel direct oxidation of the lignin on fiber surfaces and a phenol/phenoxy cyclic mediator process in the suspension liquid could accordingly describe laccase-catalyzed oxidation of beech wood fibers. Cytochrome c assays for detection of superoxide in systems involving lignin oxidized by oxidoreductases should be used with caution, as cytochrome c may be reduced by species other than superoxide. Received: 24 March 1997 / Received revision: 27 May 1997 / Accepted: 1 June 1997     

Living wood fibers act as large-capacity ��single-use�� starch storage in black locust (Robinia pseudoacacia)

A living wood fiber (LWF) is one that retains the living protoplast. LWFs store numerous starch grains during the dormant period. In black locust (Robinia pseudoacacia), almost all wood fibers in the outer part of the annual ring are LWFs. In the outermost ring, starch is accumulated during the summer, retained in winter, and metabolized during spring. We determined the starch content of LWFs, ray parenchyma, and axial parenchyma using image analysis. More than 70% of the starch grains in the outermost ring were stored in LWFs during winter. After the breakdown of starch in spring, LWFs resulted in cell death. These results indicate that LWFs in black locust function as “single-use” large-capacity starch storage.     

Analysis of exposed cellulose surfaces in pretreated wood biomass using carbohydrate‐binding module (CBM)–cyan fluorescent protein (CFP)

In enzymatic saccharification of lignocellulosics, the access of the enzymes to exposed cellulose surfaces is a key initial step in triggering hydrolysis. However, knowledge of the structure–hydrolyzability relationship of the pretreated biomass is still limited. Here we used fluorescent‐labeled recombinant carbohydrate‐binding modules (CBMs) from Clostridium josui as specific markers for crystalline cellulose (CjCBM3) and non‐crystalline cellulose (CjCBM28) to analyze the complex surfaces of wood tissues pretreated with NaOH, NaOH–Na₂S (kraft pulping), hydrothermolysis, ball‐milling, and organosolvolysis. Japanese cedar wood, one of the most recalcitrant softwood species was selected for the analysis. The binding analysis clarified the linear dependency of the exposure of crystalline and non‐crystalline cellulose surfaces for enzymatic saccharification yield by the organosolv and kraft delignification processes. Ball‐milling for 5–30 min increased saccharification yield up to 77%, but adsorption by the CjCBM–cyan fluorescent proteins (CFPs) was below 5%. Adsorption of CjCBM–CFPs on the hydrothermolysis pulp were less than half of those for organosolvolysis pulp, in coincidence with low saccharification yields. For all the pretreated wood, crystallinity index was not directly correlated with the overall saccharification yield. Fluorescent microscopy revealed that CjCBM3–CFP and CjCBM28–CFP were site‐specifically adsorbed on external fibrous structures and ruptured or distorted fiber surfaces. The assay system with CBM–CFPs is a powerful measure to estimate the initiation sites of hydrolysis and saccharification yields from chemically delignified wood pulps. Biotechnol. Bioeng. 2010; 105: 499–508. © 2009 Wiley Periodicals, Inc.     

Efficiency evaluation of activated sludge treatments of wastewater from fiber board manufacturing

Summary Wastewater from fiber board manufacture consisting in a mixture of Pinus radiata, Eucaliptus globulus and Laureliopsis phillipiana (tepa) (3:1:1) has been studied in laboratory scale activated sludge reactors with organic load rate range of 50–1700 gCOD/m³.d. A stable operation at high organic load rate with hydraulic retention time of one day was achieved. Purification efficiencies up to 90 % of COD removal could be achieved in an activated sludge treatment of fiber board wastewater working with 1 day HRT for wood log cooking wastewater and with 4 days HRT when glueing wastewater is added to the cooking wastewater treatment. Suspended solids, color and phenol concentration were negligible in the efluent of the activated sludge system.     

钙离子浓度对青檀生长和檀皮质量的影响

以Hoagland完全营养液为基质,利用5、10和15mmol·L^-13个Ca^2+浓度处理水平及一个无钙对照处理。对青檀苗木各生物组分积累的钙含量、生物量、密度、纤维长度、纤维宽度和纤维素含量进行测定分析．结果表明。对照处理下的青檀苗大部分死亡,且生长不良,其高生长量仅为有钙处理的50％左右;在有钙处理中,青檀一年苗的高生长和生物量差异不明显,但以10mmol·L^-1钙处理浓度的生长量和生物量最大;Ca^2+促进了根、叶和檀皮中钙的积累,并随着Ca^2+浓度的增加而提高,其分布为根>叶>檀皮;浓度钙处理对青檀木质部和檀皮密度、青檀木质部和檀皮的纤维形态影响不显著,其中10mmol·L^-1钙处理下木质部纤维长度和宽度最大,5mmol·L^-1钙处理下檀皮的纤维长度和长／宽比最大;不同钙处理间,檀皮(韧皮部)纤维均在2．0mm以上,檀皮的纤维长／宽比约为木质部长宽比值的4倍;浓度钙处理对青檀木质部和檀皮中纤维素含量有显著影响,且均以10mmol·L^-1。钙处理下纤维素含量最高．     

Functional anatomy of five endangered tropical timber wood species of the family Dipterocarpaceae

Wood anatomy of five dipterocarp species endemic to the Philippines was studied with the goal to explore functional wood traits of ecological significance. Stem wood of 6-year-old trees grown under similar environmental conditions in a plantation (Leyte, Philippines) was used. Wood densities decreased in the following order Hopea plagata > Dipterocarpus kerrii > Parashorea malaanoman > Shorea almon ≈ Shorea contorta. This was mainly caused by significantly thicker fiber cell walls of H. plagata and D. kerrii than those of the other three species. Wood density was negatively correlated with the abundance of axial parenchyma cells. Predicted conductance was independent from wood density and lowest in H. plataga and highest in D. kerrii and S. contorta. These results indicate that H. plagata and D. kerrii is woods have higher constructions costs in term of carbon per unit of biomass, and that H. plagata is probably better acclimated to varying soil moisture than the other species.