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Intrinsic Regulation of Diameter Growth in Woody Plants
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Intrinsic Regulation of Diameter Growth in Woody Plants

A special issue of Forests (ISSN 1999-4907). This special issue belongs to the section "Forest Ecophysiology and Biology".

Deadline for manuscript submissions: closed (31 March 2023) | Viewed by 24144

Special Issue Editor

Dr. Rodney Arthur Savidge

E-Mail Website
Guest Editor
University of New Brunswick, Fredericton, NB, Canada
Interests: cell biology and biochemistry; cellular differentiation

Special Issue Information

Dear Colleagues,

Secondary or diameter growth in perennial plants occurs through water, photosynthate and nutrient allocation in support of cellular metabolism, division, expansion and differentiation phenomena within interfascicular cambium, cortical tissues, vascular cambium and phellogen. These phenomena and tolerance of stems and roots to changing environments are crucially important for the survival of perennial woody species, and their explanations reside in genetics, biochemistry, biophysics and cell biology. This Special Issue will review the state of knowledge and present new findings on how secondary growth is regulated, with particular emphasis on the need to understand the basis for survival fitness and sustainability of woody species in a changing biosphere.

Dr. Rodney Arthur Savidge
Guest Editor

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Keywords

  • anatomy
  • branches
  • cellulose
  • dormancy
  • gene expression
  • hemicelluloses
  • juvenile wood
  • lignins
  • phloem
  • phytohormones
  • reaction wood
  • xylem
  • cortex
  • phellogen

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Published Papers (9 papers)

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Editorial

Jump to: Research, Review

11 pages, 13241 KiB  
Editorial
Intrinsic Regulation of Diameter Growth in Woody Plants
by Rodney Arthur Savidge
Forests 2023, 14(5), 1065; https://doi.org/10.3390/f14051065 - 22 May 2023
Cited by 1 | Viewed by 1345
Abstract
The defining feature of each forest is the organism that humanity generically designates as ‘tree’ [...] Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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Research

Jump to: Editorial, Review

16 pages, 10479 KiB  
Article
Seasonal Cambial Activity and Formation of Secondary Phloem and Xylem in White Oaks (Quercus alba L.)
by Marcelo R. Pace, Rafaella Dutra, Carmen R. Marcati, Veronica Angyalossy and Ray F. Evert
Forests 2023, 14(5), 920; https://doi.org/10.3390/f14050920 - 28 Apr 2023
Cited by 3 | Viewed by 3327
Abstract
(1) Background: the cambium has seasonal activity, forming earlywood and early phloem with relatively wide conducting cells, which will function during the most favorable season, and latewood and late phloem with narrower conducting cells, which typically function during the less favorable season. However, [...] Read more.
(1) Background: the cambium has seasonal activity, forming earlywood and early phloem with relatively wide conducting cells, which will function during the most favorable season, and latewood and late phloem with narrower conducting cells, which typically function during the less favorable season. However, few studies have focused on when these two contrasting tissue types are formed in relation to climatic conditions. (2) Methods: the senior author of this paper made weekly collections for an entire year of four specimens per collection back in the 1960s, using traditional anatomical methods to study in detail what the cambium was producing progressively. (3) Results: annual growth rings are evident in both secondary xylem and secondary phloem. The cambium resumes activity in early April, with simultaneous formation of wood and secondary phloem. Both latewood and late phloem production are initiated in early June, the peak of the favorable season. The cambium ends its activity in early August. Phloem growth rings are marked by radially narrow sieve elements interspersed among a band of axial parenchyma with dark contents. Most specimens produce only one fiber band per season. This feature may be used as an indirect phloem growth ring marker. Wood growth rings are marked by very wide vessels and thick-walled, radially narrow fibers. (4) Conclusions: growth rings are evident in both secondary xylem and secondary phloem. The trees produce their latewood and late phloem long before the beginning of autumn, indicating that they prepare ahead of the selective regime, a phenomenon most likely dependent on the photoperiod. Living sieve elements are present yearlong. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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26 pages, 51483 KiB  
Article
Vascular Cambium—Between the Hammer and the Anvil: A Tensile Stress Hypothesis on the Mechanism of Radial Growth of Broadleaved Trees
by Paweł Kojs, Adam Miodek, Aldona Paulina Miodek and Wiesław Włoch
Forests 2023, 14(4), 823; https://doi.org/10.3390/f14040823 - 17 Apr 2023
Cited by 2 | Viewed by 2584
Abstract
The vascular cambium is the main lateral meristem responsible for the secondary growth of trees. There are a number of explicit and implicit assumptions behind this statement which allow questions to be raised about the mechanism underlying the radial growth of trees. Based [...] Read more.
The vascular cambium is the main lateral meristem responsible for the secondary growth of trees. There are a number of explicit and implicit assumptions behind this statement which allow questions to be raised about the mechanism underlying the radial growth of trees. Based on the hypothesis of the diurnal strains of plant organs, it is anticipated that the process of radial growth can be understood as an adaptation to the cyclically changing mechanical stress in the radial direction generated by the phloem during the 24 h day cycle. This qualitative hypothesis treats cambium as a tissue subjected to nighttime stretching and daytime compression in the radial direction. The proposed osmo-mechanical hypothesis of the radial growth of vascular cambium links the daily change in water status and the considerable daily strains in the xylem and phloem with the radial net expansion of a tree trunk. We highlight transpiration as a major factor influencing the secondary growth of woody plants. Thus, we indirectly relate all the biotic (e.g., insect infestation, fungi infections, injuries, shadowing, intra- and interspecies competition, parasitism, symbiosis, etc.) and abiotic (e.g., humidity, water availability, wind, injuries, shadowing, day length in a vegetative season, altitude, temperature, insolation, etc.) processes influencing transpiration with radial growth. In the proposed hypothesis, we also infer that differences in the strains in phloem and xylem are the direct source of tensile stress, tensile stress relaxation, compressive stress, and compressive stress relaxation in the vascular cambium. This sequence appears to be crucial in understanding both the process of the radial growth of trees and the formation of differential wood patterns, within the same genotype as well as in different genotypes. It also provides arguments for the discussion on the mechanisms regulating processes in the vascular cambium. It points out the important role of the variable mechanical stresses in the radial, circumferential, and axial directions and their interference in the development of this lateral meristem. Thus, this hypothesis supports the concept of the epigenetic and systemic regulation of intrinsic wood patterns and tree forms by environmental factors. The hypothesis is focused exclusively on broadleaved trees and symplastic growth. This limitation of the scope is due to a concern for clarity. In this form, the hypothesis provides an alternative explanation for a pure process of radial growth and paves the way for a better interpretation of such phenomena as earlywood and latewood formation. At the same time, this approach to the vascular cambium provides answers to many questions related to the generation of the mechanical conditions necessary for the occurrence of intrusive growth between tangential cell walls; this is of fundamental importance for fusiform initials readjustment, vessel element and fibre formation, ring-porous wood formation, etc. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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14 pages, 3797 KiB  
Article
Distribution of Plant Hormones and Their Precursors in Cambial Region Tissues of Quercus myrsinifolia and Castanopsis cuspidata var.sieboldii after Bending Stems or Applying Ethylene precursor
by Yoshio Kijidani, Taku Tsuyama and Yuji Tokumoto
Forests 2023, 14(4), 813; https://doi.org/10.3390/f14040813 - 15 Apr 2023
Cited by 3 | Viewed by 1664
Abstract
The role of plant hormones in tension wood (TW) formation has been studied but is still unclear. IAA, ABA, ACC, tZ, tZR, iP, and iPR in cambial region tissues were identified and quantified by liquid chromatography/mass spectrometry (LC/MS). We examined the distribution of [...] Read more.
The role of plant hormones in tension wood (TW) formation has been studied but is still unclear. IAA, ABA, ACC, tZ, tZR, iP, and iPR in cambial region tissues were identified and quantified by liquid chromatography/mass spectrometry (LC/MS). We examined the distribution of plant hormones and their precursors in the stems of Quercus myrsinifolia Blume and Castanopsis cuspidata var.sieboldii Nakai after bending the stems or applying an ethylene precursor (ACC). After 3 weeks of bending, though not after 1 week of bending, the auxin (IAA) and abscisic acid (ABA) amounts were larger on the TW side than on the opposite wood (OW) side and in upright trees. After 2 weeks of bending, the peak concentrations of IAA in cambium on the TW side were obviously higher than those on the OW side. After 1 week of bending, the ACC amounts on both sides were larger than in upright trees, but after 3 weeks of bending, they were smaller than in upright trees. Applied ACC did not enhance TW formation but induced axical parenchyma and phloem formation in C. cuspidata var.sieboldii. These results indicated that the distribution patterns of IAA and ABA might have important roles in TW formation in these two species. The role of ACC might be limited in the early stages of TW formation. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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13 pages, 1587 KiB  
Article
Seasonal, Monthly, Daily, and Diel Growth, and Water Status Dynamics of Balsam Fir in a Cold and Humid Boreal Environment
by Shalini Oogathoo, Louis Duchesne, Daniel Houle, Daniel Kneeshaw and Nicolas Bélanger
Forests 2023, 14(4), 802; https://doi.org/10.3390/f14040802 - 13 Apr 2023
Cited by 3 | Viewed by 1782
Abstract
Despite new knowledge in recent years, our understanding of the phenology of wood formation for various species growing in different environments remains limited. To enhance our knowledge of the tree growth dynamics of boreal tree species, we investigated the average seasonal, monthly, daily, [...] Read more.
Despite new knowledge in recent years, our understanding of the phenology of wood formation for various species growing in different environments remains limited. To enhance our knowledge of the tree growth dynamics of boreal tree species, we investigated the average seasonal, monthly, daily, and diel patterns of tree growth and water status from 11 years of observations with the 15 min and 1.5 µm resolved stem radial size variation data of 12 balsam fir (Abies balsamea (L.) Mill.) trees growing in a cold and humid boreal environment. Growth only occurred above an air temperature threshold of 9–10 °C, and the maximal growth rate over the year (23–24 June) was synchronous with the maximal day length (20–21 June) and not with the maximal air temperature, which occurred on average about 2 weeks later (4–5 July). Tree growth was mostly restricted by air temperature and solar radiation under these cold and wet boreal conditions, but our results also highlight a turgor-driven growth mechanism. Diel dynamics reveal that tree growth is minimal during the day when the stem dehydrates, and higher past midnight when the stem is fully rehydrated. This pattern suggests that carbon assimilation through photosynthesis occurs primarily during the day, while energy production and carbon allocation to woody tissues occur primarily at night via cellular respiration. Overall, our results show that the temporal patterns of the growth and water status of balsam fir growing in cold and humid boreal environments are controlled by a set of environmental factors that influence various physiological processes and mechanisms, many of which still need to be documented. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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32 pages, 37160 KiB  
Article
Gišogenetic Variation in White-Spruce (Picea glauca (Moench) Voss) Trees of Yukon Beringia, Canada
by Rodney Arthur Savidge, Xin Yuan and Hartmut Foerster
Forests 2023, 14(4), 787; https://doi.org/10.3390/f14040787 - 11 Apr 2023
Cited by 2 | Viewed by 1833
Abstract
Gišogenesis, otherwise known as secondary-xylem development, was investigated in an old-growth upland population of white spruce (Picea glauca (Moench) Voss) trees having morphologically diverse crowns and growing on a south slope north of East Fork Creek bordering never-glaciated Yukon Beringia. After tree [...] Read more.
Gišogenesis, otherwise known as secondary-xylem development, was investigated in an old-growth upland population of white spruce (Picea glauca (Moench) Voss) trees having morphologically diverse crowns and growing on a south slope north of East Fork Creek bordering never-glaciated Yukon Beringia. After tree felling, trunks were segmented into one-metre lengths. In the laboratory, widths of xylem layers were measured across the four cardinal directions at each height, followed by Pearson’s product momentum correlations to evaluate variation in historical gišogenetic vigour within and between trees. Substantial variation was found, and it cannot readily be explained in terms of differences in extrinsic environment. Physiological differences in intrinsic gišogenetic regulation within a genetically diverse population, comprising both refugia and recent recruits, is proposed as a probable explanation, thus emphasizing the individuality of each tree’s internal control over how it responds to the extrinsic environment. Further investigations within Yukon Beringia may yield insight into evolutionary diversification of gišogenesis. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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22 pages, 6927 KiB  
Article
Changes in the Differentiation Program of Birch Cambial Derivatives following Trunk Girdling
by Aleksandra A. Serkova, Tatiana V. Tarelkina, Natalia A. Galibina, Kseniya M. Nikerova, Yulia L. Moshchenskaya, Irina N. Sofronova, Nadezhda N. Nikolaeva, Diana S. Ivanova, Ludmila I. Semenova and Ludmila L. Novitskaya
Forests 2022, 13(8), 1171; https://doi.org/10.3390/f13081171 - 23 Jul 2022
Cited by 7 | Viewed by 2283
Abstract
The mechanisms regulating the tree trunk radial growth can be studied in original experiments. One technique for studying cambium activity (the meristem involved in radial growth) under conditions of an increased photoassimilate level is trunk girdling. We girdled the trunks of 17- to [...] Read more.
The mechanisms regulating the tree trunk radial growth can be studied in original experiments. One technique for studying cambium activity (the meristem involved in radial growth) under conditions of an increased photoassimilate level is trunk girdling. We girdled the trunks of 17- to 22-year-old silver birch plants (Betula pendula Roth var. pendula) during the active growth period and collected xylem and phloem samples at two height levels (1 cm and 35 cm) above girdle, 10, 20, and 30 days after girdling. We investigated the changes that occurred at the anatomical level, as well as the activities of sucrose-metabolizing enzymes and antioxidant-system enzymes and the expression of genes that encode proteins involved in sucrose and auxin transport and metabolism. A moderate increase in photoassimilates (35 cm above the girdle) resulted in a change in the ratio of phloem to xylem increments and an increase in the proportion of parenchyma in the conducting tissues. The increase of photoassimilates above the level at which they can be used in the processes of normal tissue growth and development (1 cm above the girdle) led to xylogenesis suppression and the stimulation of phloem formation, a significant increase in the parenchyma proportion in the conducting tissues, and formation of large sclereid complexes. The differentiation of parenchyma and sclereid cells coincided with biochemical and molecular markers of abnormal conducting tissue formation in Karelian birch, which are also characterized by high proportions of parenchyma and sclereid near the cambium. The results obtained are important in understanding the cambium responses to the photoassimilate distribution changes and estimating tree productivity and survival under changing environmental conditions. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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Review

Jump to: Editorial, Research

22 pages, 5353 KiB  
Review
Shoot Phenology as a Driver or Modulator of Stem Diameter Growth and Wood Properties, with Special Reference to Pinus radiata
by Rowland D. Burdon
Forests 2023, 14(3), 570; https://doi.org/10.3390/f14030570 - 13 Mar 2023
Cited by 2 | Viewed by 1481
Abstract
Seasonal phenology is expressed in the annual rhythms of growth and quiescence, which may range from being sharply defined to weakly quantitative. These rhythms, both vegetative and reproductive, are a key aspect of a plant’s survival strategy. They enable the plant to both [...] Read more.
Seasonal phenology is expressed in the annual rhythms of growth and quiescence, which may range from being sharply defined to weakly quantitative. These rhythms, both vegetative and reproductive, are a key aspect of a plant’s survival strategy. They enable the plant to both survive seasonal stresses and take advantage of favourable conditions, while making pollination efficient through synchronised flowering. Maturation in woody perennials causes some ontogenetic modulation of seasonal phenology. Shoot phenology is driven by various environmental cues, notably temperatures and daylength, with shoot extremities often being prime receptors. The phenology of shoot extremities is in turn seen as a strong driver of cambial activity, which itself is an aspect of shoot phenology and the basis of stem diameter growth. The aspects of cambial activity reflecting hoot–tip phenology primarily involve the timing of xylem formation and the anatomical and physical properties of xylem cells. The actual amount of diameter growth, however, is governed much more by other factors, notably the growth potential of the species, the space for the tree to grow in, and how favourable local conditions are for growth. Somehow, all tree species allocate resources to shoot extension and diameter growth to represent viable adaptive strategies, although there is no identified role of phenology per se in such allocation. Among species, Pinus radiata is extremely important commercially, largely through a high growth potential that reflects distinctive phenology. Much research on the species provides a basis for linking its phenology and shoot–tip architecture to seasonal timing of diameter growth and fine details of within-ring variation in xylem cell properties. This provides a baseline for comparison with many other tree species, conifers and hardwoods. Selected examples are considered to illustrate the range of adaptive strategies. Regulation of diameter growth and internal variation in wood properties reflects the response to competitive pressures. Modifying the regulation to optimise wood production and quality poses a great challenge for future domestication. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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43 pages, 20842 KiB  
Review
Inter- and Intraxylary Phloem in Vascular Plants: A Review of Subtypes, Occurrences, and Development
by Kishore S. Rajput, Kailas K. Kapadane, Dhara G. Ramoliya, Khyati D. Thacker and Amit D. Gondaliya
Forests 2022, 13(12), 2174; https://doi.org/10.3390/f13122174 - 17 Dec 2022
Cited by 5 | Viewed by 6299
Abstract
Phloem is one of the vital tissues of the vascular system that plays a crucial role in the conduction of photosynthates. In vascular plants, it develops external to the vascular cambium but in a small fraction of eudicots (formerly known as dicots), it [...] Read more.
Phloem is one of the vital tissues of the vascular system that plays a crucial role in the conduction of photosynthates. In vascular plants, it develops external to the vascular cambium but in a small fraction of eudicots (formerly known as dicots), it occurs within (interxylary) and inside (intraxylary) the secondary xylem. Ontogenetically, it is classified as Strychnos, Combretum, Azima, and Calycopteris types. In all four cases, phloem islands remain enclosed within the secondary xylem but each has unique origins. Similarly, the deposition of the phloem at the pith margin is common in several plants. It develops from procambial derivatives or adjacent pith cells or by initiating an intraxylary phloem cambium. Functionally, this cambium can produce only phloem or both secondary xylem and phloem. In some instances, the deposition of the secondary xylem and phloem in the same direction has also been documented. Some experimental evidence is available on the role of phloem but is it applicable to inter- and intraxylary phloem? The presence of inter- and intraxylary phloem is attributed to a defence mechanism against insects or plants that show sudden and enormous flowering or it can correlate with high temperatures or an unconducive climate in a desert region where sieve tube elements have become nonfunctional due to high temperatures. The present review is an attempt to analyse the role of interxylary and intraxylary phloem. Full article
(This article belongs to the Special Issue Intrinsic Regulation of Diameter Growth in Woody Plants)
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