Effects of environmental factors on wood formation in Scots pine stems

Summary To find the optimal conditions for growth and development of tracheid walls in Scots pine stems the effects of temperature and precipitation on xylem cell production by the cambium, radial cell expansion and secondary wall thickening have been studied. The observations were carried out on 10 specially chosen 50 to 60-year-old trees, growing in central Siberia, over 2 seasons. The data on the number of cells in differentiation zones and mature xylem along radial rows of tracheids, radial and tangential sizes of tracheids and their lumens were used for calculating cambial activity, the rates and durations of cell development in the zones, and both the thickness and cross sectional areas of tracheid walls. The mean day, mean maximal diurnal and mean minimal nocturnal temperatures have been shown by correlation and regression analyses to affect differentially separate stages of cytogenesis. The temperature influenced the initial division the side of xylem and radial cell expansion mainly in May–June, while the influence of precipitation increased in July–August. Throughout all seasons it was the temperature that had the main influence on the biomass accumulation in cell walls. Optimal values of temperature and precipitation for cell production by cambium, radial cell expansion and secondary wall thickening have been calculated. The data are discussed in connection with productivity and quality of wood.     

Daylength Effects on Growth, Tracheid Development, and Photosynthesis in Seedlings of Picea sitchensis and Pinus sylvestris

Effects of change in daylength on tracheid expansion and tracheidwall thickening are considered in relation to shoot and rootgrowth, assimilation rate, and starch content, in seedlingsof Picea sitchensis and Pinus sylvestris grown in controlledenviroments. Rates of wall thickening decreased in the first tracheids tobegin wall thickening after decrease in daylength. A sharp decreasein starch-grain size at the same time supports previous suggestionsthat wall thickness is related to available substrate; however,rates of assimilation were found to be far greater in shortdays than in long, suggesting that a surplus of carbohydratemay be produced in long days. It is pointed out that if availablesubstrate does limit wall thickening it is likely to determineto al accumulation of wall material; wall material per tracheidwould follow logistically from this depending on the numberof tracheids around the xylem, and wall thickness would dependalso on the radial tracheid diameter. Unexpectedly, rate of shoot growth accelerated after transferto short days before its final cessation with terminal-bud formation.Root growth declined in short days, but later increased againafter terminal bud formation. Rate of root growth did not appearto be associated with tracheid development in the shoot.     

Effects of environmental factors on wood formation in larch (Larix sibirica Ldb.) stems

 Effects of temperature and precipitation on xylem cell production by the cambium, radial cell expansion and secondary wall thickening in larch stems have been studied. The observations were carried out over two seasons on ten 50- to 60-year-old trees, growing in central Siberia and chosen according to growth rate (the number of cells in radial rows of each of two of the preceding seasons was equal). The data on the number of cells in differentiation zones and mature xylem along radial rows of tracheids, radial and tangential sizes of tracheids and their lumina were used for calculating cambial activity, the rates and durations of cell development in the zones, and both the thickness and cross-sectional areas of tracheid walls. The mean day air temperature, mean maximum diurnal and mean minimum nocturnal temperatures as well as precipitation have been shown by correlation and regression analyses to affect differentially separate stages of tracheid differentiation. Throughout all the seasons it was temperature that had the main influence on the initial divisions in the xylem, radial cell expansion and biomass accumulation. However, the levels of such an effect on separate stages of cytogenesis were different, especially the influence of nocturnal temperature on xylem cell production by cambium and primary wall growth. The optimum values of temperature and precipitation for cell production by cambium, for radial cell expansion and secondary wall thickening have been calculated. These optimum values of the first and second processes proved to be practically equal, while the last differs considerably in response to temperature. The data are discussed in connection with formation of early and late tracheids. Received: 3 July 1996 / Accepted: 7 February 1997     

Temperature and Tracheid Development in Pinus sylvestris Seedlings

Seedlings of Pinus sylvestris were grown in long days at day/nighttemperatures of 27.5/20 °C. 22.5/15 °C, and 17.5/10°C to determine effects of temperature on tracheid expansionand wall thickening. Inbuilt regulatory systems make it unlikely that mean temperaturedifferences account for much of the normal seasonal variationin tracheid dimensions, for while an increase in temperatureincreased rates of both tracheid expansion and wall thickening,the duration of both was reduced. Though wall thickness increasedwith decreasing temperature in tracheids at the same distancefrom the pith, this was offset by a slower rate of tracheidproduction at lower temperatures. While rates of wall accumulation increased with increase intemperature, storage starch grain sizes were smaller at highertemperatures. It is suggested that wall thickness is not limitedby available substrates in these conditions.     

Daily dynamics in xylem cell radial growth of Scots pine (Pinus sylvestris L.)

Daily dynamics of radial cell expansion during wood formation within the stems of 25-year-old Scots pine trees (Pinus sylvestris L.), growing in field conditions, were studied. The samples of forming wood layers were extracted 4 times per day for 3 days. Possible variations in the growth on different sides of the stem, duration of cell development in radial cell expansion phase and dynamics of cell growth in this phase were taken into account. The perimeters of tracheid cross-sections as a reflection of primary cell wall growth were the criterion of growth in a radial direction. For the evaluation of growing cell perimeters a special system for digital processing and image analysis of tracheid cross-sections of the forming wood was used. Growth rate for certain time intervals was estimated by the change in the relation of the perimeter of each observed cell in each of ten tracheid rows in each of 12 trees to the perimeter of the xylem cell of the same row before the expansion. Temporal differences in average values of the relations were estimated by Analyses of Variance. The existence of daily dynamics of Scots pine xylem cell radial growth has been proved. Intensive growth of pine tracheids has been shown to occur at any time of the day and to depend on the temperature regime of the day and the night as well as water supply of stem tissues. Moreover, reliable differences (P = 0.95) in the increment of cell walls during tracheid radial expansion have been found. Pulsing changes of the water potentials both of the cell and the apoplast, as the reason for the fluctuations of radial cell growth rate, were discussed.     

Effects of Light Intensity on Tracheid Dimensions in Picea sitchensis

In seedlings of Picea sitchensis grown in constant conditions,or within older trees in the field, light intensity had no neteffect on the wall thickness of tracheids produced at the samepoint in time. This appears to be due to a balanced regulatorysystem, effects of light intensity on rate of accumulation ofwall volume per leaf being offset by differences in rate ofxylem increment, and differences in wall material per tracheidbeing nullified in their effects on wall thickness by effectson tracheid diameter. Mean tracheid wall thickness across the growth ring increasedwith light intensity, due to increase in proportion of late-woodassociated with the longer duration of cambial activity at higherlight intensity, duration of wall thickening increasing duringthe season. Duration of wall thickening did not vary with lightintensity. The rate of increase in wall volume was limited by light intensity(and hence possibly by substrate availability) at all lightintensities in the field, but in seedlings in controlled conditionsthe rate of wall production was no greater at 20 000 lx thanat 6700 lx.     

The effects of tracheid dimensions on variations in maximum density of Picea glehnii and relationships to climatic factors

An investigation was made of the effects of tracheid dimensions on variations in the maximum density of Picea glehnii Mast., which were associated with climatic changes. Radial cell diameter and the thickness of the tangential cell walls of the last-formed cells in 90 annual rings of nine trees with different annual ring widths were analyzed by image analysis. Correlations between maximum density and tracheid dimensions indicated that changes in maximum density were due mainly to changes in cell wall thickness of the last-formed cells in annual rings and were not due to changes in radial cell diameter. The effects of climatic factors on tracheid dimensions were examined by application of dendroclimatological techniques. A chronology of cell wall thickness that represented common signals among trees was established. Simple correlation and response function analyses of the chronology revealed that cell wall thickness was influenced positively by summer temperature and negatively by precipitation in August, and these responses were similar to those of maximum density. The study demonstrated that variations in maximum density were due to variations in the cell wall thickness of the last-formed cells, which varied depending on the weather in summer. Received: 8 February 1999 / Accepted: 7 October 1999     

A Comparison of Root- and Shoot-wood Development in Conifer Seedlings

Tracheid diameter, wall thickness, and wall area per tracheidincreased towards the root tip in first-year seedlings of Piceasitchensis and Pinus sylvestris; this is shown to be associatedwith differences in duration of the expansion and wall thickeningphases of tracheid development. Transfer to short days producesa similar response throughout the plant, tracheid diameter andwall thickness decreasing shortly after transfer, due to a declinein rate of development. These data are discussed in relationto growth-regulator gradients likely to exist between root andshoot. It is pointed out that though effects of growth regulatorson tracheid dimensions are well documented, it has yet to beestablished whether this is due to their regulation of the rateor of the duration of development.     

Substrate Availability in Relation to Daylength Effects on Tracheid Development in Picea sitchensis (Bong) Carr

Changes in assimilation and growth were studied in Picea sitchensis(Bong) Carr. seedlings initially grown in long days and subsequentlytransferred to short days. These results, and some from a supplementarystudy involving transfer to reduced light quantity alone, wereexamined in relation to tracheid development. Increases in photosynthesis conditioned by reduced daylengthwere greater in magnitude than those resulting from a reductionin light quantity alone. Possible reasons for this as well asthe apparent absence of such photoperiodic effects in the fieldare discussed. Following a reduction in daylength, ¹⁴C incorporation into reservesand new growth generally decreased while turnover materialsincreased in prominence. Some local changes in this generalpattern were apparent, these changes being consistent with growthchanges in the organs under consideration. Initial changes in tracheid wall thickness and diameter aftershort-day transfer appear to be correlated with expected andobserved changes in endogenous substrate, the results for tracheiddiameter confirming a previous observation that substrate levelexerts an important modifying influence on tracheid radial expansion.     

Effects of Environmental Change on Wood Production and Wood Structure in Picea sitchensis Seedlings

Changes in environment that would be expected to reduce substrateavailability, decrease the rate of xylem increment, tracheiddiameter and wall thickness, in seedlings of Picea sitchensis.But after reaching a minimum about 10 days to 3 weeks afterenvironmental change, xylem increment, tracheid wall thickness,and in some instances tracheid diameter, increase again up toabout 4 to 6 weeks after transfer. This recovery parallels arecovery in net assimilation rate, and is associated with anincrease in photosynthetic efficiency. Although the light intensity and temperature treatments imposedwere more drastic than those that would normally be expectedin the field, they had remarkably little net effect on tracheiddimensions. On the other hand change in photoperiod producedgreater changes in tracheid dimensions, photoperiodic effectsbeing superimposed on effects of change in substrate availability.It is suggested that adaptation to reduced substrate will bufferthe plant against climatic fluctuations during the growing season,while the photoperiodic response will ensure preparation forwinter dormancy. It is concluded that the major seasonal changes in tracheiddimensions are unlikely to be caused by variation in substrateavailability. Changes in light intensity and temperature haveminor effects on wood production and structure through effectson substrate availability, but the major seasonal trends aremore likely to be associated with changes in growth regulationproduction.     

Mechanical reinforcement of tracheids compromises the hydraulic efficiency of conifer xylem

Wood structure and function of juvenile wood from 18 conifer species from four conifer families (Araucariaceae, Cupressaceae, Pinaceae and Podocarpaceae) were examined for a trade-off between wood reinforcement and hydraulic efficiency. Wood density and tracheid 'thickness-to-span' ratio were used as anatomical proxies for mechanical properties. The thickness:span represented the ratio of tracheid double wall thickness to lumen diameter. Hydraulic resistivity (R) of tracheids on a cross-sectional area basis (RCA) increased over 50-fold with increasing density and thickness:span, implying a strength versus efficiency conflict. The conflict arose because density and thickness:span were increased by narrowing tracheid diameter rather than by thickening walls, which may be developmentally difficult. In the Pinaceae and Cupressaceae species, density and thickness:span correlated strongly with protection from drought-induced embolism, suggesting that mechanical strength was required in part to withstand tracheid collapse by negative sap pressure. These species showed a corresponding trade-off between increasing RCA and embolism protection. In contrast, species of Podocarpaceae and Araucariaceae were overbuilt for their embolism protection and were hydraulically inefficient, having greater density, thickness:span and RCA, none of which were correlated with vulnerability to embolism.     

Some quantitative effects of indoleacetic acid on the wood production and tracheid dimensions of Picea

The diameter and wall thickness of tracheids produced after indoleacetic acid treatment were not significantly different from those of the intact controls, for the first few weeks after treatment of disbudded shoots of Picea abies Karst. and Picea sitchensis (Bong.) Carr. However, lateral application of indoleacetic acid (IAA) to intact shoots increased both tracheid diameter and wall thickness; it is suggested that IAA acted synergistically with another endogenous growth regulator, which was also removed by disbudding. Increase in wall thickness after exogenous IAA was associated with increase in duration of the wall thickening phase of tracheid differentiation; this is discussed in relation to the seasonal change from early to latewood. Cambial dormancy was induced by disbudding during active wood production. Since this occurred with or without the presence of current leaves, it is concluded that in Picea continued cambial activity depends upon supply of auxin from the buds, and cannot be supplied from expanded leaves or from the internode itself. Neither indoleacetic acid nor gibberellic acid stimulated renewed cambial activity when applied after the cessation of wood production. With both disbudded and intact shoots, the effectiveness of exogenous IAA declined with time, probably due to decreasing penetration through callus developing at the wounded surface. It is suggested that this apparent change in IAA effectiveness may explain some discrepancies between the results of previous observers.Abbreviations IAA Indoleacetic acid - GA₃ Gibberellic acid     

Stem wood properties of mature Norway spruce after 3 years of continuous exposure to elevated [CO2] and temperature

The objective of the study was to investigate the interactive effects of elevated atmospheric carbon dioxide concentration, [CO₂], and temperature on the wood properties of mature field-grown Norway spruce ( Picea abies (L.) Karst.) trees. Material for the study was obtained from an experiment in Flakaliden, northern Sweden, where trees were grown for 3 years in whole-tree chambers at ambient (365 μmol mol⁻¹) or elevated [CO₂] (700 μmol mol⁻¹) and ambient or elevated air temperature (ambient +5.6 °C in winter and ambient +2.8 °C in summer). Elevated temperature affected both wood chemical composition and structure, but had no effect on stem radial growth. Elevated temperature decreased the concentrations of acetone-soluble extractives and soluble sugars, while mean and earlywood (EW) cell wall thickness and wood density were increased. Elevated [CO₂] had no effect on stem wood chemistry or radial growth. In wood structure, elevated [CO₂] decreased EW cell wall thickness and increased tracheid radial diameter in latewood (LW). Some significant interactions between elevated [CO₂] and temperature were found in the anatomical and physical properties of stem wood (e.g. microfibril angle, and LW cell wall thickness and density). Our results show that the wood material properties of mature Norway spruce were altered under exposure to elevated [CO₂] and temperature, although stem radial growth was not affected by the treatments.     

Ascorbic acid and xylem development in trunks of the Siberian larch trees

The contents of ascorbic acid (AA) and its oxidized form, dehydroascorbic acid (DHA), were assessed as related to the tracheid differentiation in the course of early and late wood development in the Siberian larch (Larix sibirica Ldb.) trees. The samples of the cambium, cell enlargement zone and mature cells were collected at the successive developmental stages by scraping tissues off layer by layer from trunk segments of the 20-year-old trees according to anatomical and histochemical criteria. While cambium initials were rapidly dividing, the AA contents per dry weight and per cell considerably exceeded the corresponding values characteristic of the late xylem development; such difference corresponded to the higher number of early tracheids per annual ring, as compared to the late tracheids. The AA content decreased as cells enlarged. The radial growth of the early wood tracheids, as compared to the late wood tracheids, was accompanied with a threefold increase in the AA and a decline in the DHA contents. The AA/DHA ratio was in line with the early tracheid enlargement. The maximum AA content was observed at the early stage of the secondary cell wall thickening in the tracheids of early and late xylem preceding lignification. During this stage of early wood development, the DHA content exceeded sixfold the corresponding value in the late xylem; as a result, the initial rates of lignification were different in two tissues. The rate of lignification in a newly developing layer of the early xylem increased gradually and was the highest in the completely differentiated tracheids. In the late xylem, the lignification rate was at its highest at the very beginning and then declined in the course of tracheid maturation. The dissimilar patterns of lignification in the early and late xylem were primarily associated with the DHA content, which increased in the early xylem and decreased in the maturing late xylem. Thus, the AA content and its accessibility to oxidation in the growing and mature xylem cells exhibited the diverse developmental patterns in the early and late xylem: two tissues differed in the tracheid number and radial diameter as well as in the rate of lignification.Translated from Fiziologiya Rastenii, Vol. 52, No. 1, 2005, pp. 97–107.Original Russian Text Copyright © 2005 by Antonova, Chaplygina, Varaksina, Stasova.     

A New Species of Araucarioxylon Kraus from the Early Early Permian,Nei Mongol,China

A kind of silicified fossil wood with mixed pits on the radial tracheid wall is described. The fossil wood was collected from the top of Taiyuan Formation (early Early Permian) in Wuda Mining District, Nei Mongol. Compared with the Paleozoic fossil woods in the world, it is put into Araucarioxylon Kraus and named as A. laoshidanense sp. nov. Based on the character of possessing mixed pittings (alternate and opposite pittings) on the radial tracheid wall, the fossil wood is believed to be one of the unknown primitive conifers.Diagnosis of the new species: Only secondary xylem preserved and consisting of axial tracheids and rays. Growth ring boundary, resin duct and axial parenchyma absent. One to Four (commonly 2or3) seriates of bordered pits mostly alternate but sometimes opposite）on the radial tracheid wall. One to Four (commonly1, rarely2 to 4) Cupressoid pits in each cross-field. Rays usually uniseriate, sometimes partly-biseriate and 2 to 39 (mainly3-5) cells high.     

RAPTOR: Row and position tracheid organizer in R

Mechanistic understanding of tree-ring formation and its modelling requires a cellular-based and spatially organized characterization of a tree ring, moving from whole rings, to intra-annual growth zones and individual cells. A tracheidogram is a radial profile of conifer anatomical features, such as lumen area and cell wall thickness, of sequentially- and positionally-ranked tracheids. However, its construction is tedious and time-consuming since image-analysis-based measurements do not recognize the position of cells within a radial file, and present-day tracheidograms must be constructed manually.Here we present the R-package RAPTOR that complements tracheid anatomical data obtained from quantitative wood anatomy software (e.g., ROXAS, WinCELL, ImageJ), with the specific positional information necessary for the automated construction of tracheidograms. The package includes functions to read and visualize tracheid anatomical data, and uses local search algorithms to ascribe a ranked position to each tracheid in identified radial files. The package also provides functions to ensure that tracheids are adequately aligned for identifying the first tracheid in each radial file, and obtaining the correct ranking of tracheids along each radial file. Additional functions allow automating the analyses for multiple samples and rings (batch mode) and exporting data and plots for quality control.RAPTOR allows tracheidogram users to take advantage of the latest generation of cell anatomical measuring systems. With this R-package we aim to facilitate the construction of more robust and versatile tracheidograms for the benefit of the research community.     

Mechanism of Xylem Differentiation in Pinus silvestrisL.

The duration and daily rate of radial growth and secondary-wallformation of all consecutive, radially-formed tracheids throughoutthe season were investigated in stems of adult trees of Pinussilvestris L. It was found that (1) the variation in radial diameter of tracheidswas probably dependent on seasonal changes in the rate of growthduring the phase of radial enlargement, (2) the daily rate ofcell-wall formation determined the final cell-wall thicknessof tracheids only at the beginning and the end of the season,(3) both rates were affected by temperature, (4) seasonal changesin cell-wall thickness were dependent mostly upon seasonal changesin the duration of the maturation period, (5) the changes inthe duration of the maturation period which brought about transitionfrom early to late wood were determined mostly by the delayin onset of autolysis of cytoplasm which terminates the phaseof tracheid maturation. This process, unlike the xylem productionfrom cambium and the termination of radial enlargemnt, was foundnot to be affected by the seasonal variation of temperature. An attempt to correlate these processes with the activity ofnatural auxin extracted from the cambial region gave negativeresults. On the basis of the results obtained, auxin and environmentalfactors such as precipitation and temperature seem not to bespecific for xylem differentiation. They may seriously affectwood differentiation if they become limiting or exceed the limitof tolerance, but probably they do not determine differentiationof the annual ring of conifers into early and late wood.     

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