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(1978)
On the Influence of Geographical Position on Anatomic Structure of the Dahurian Larch Bark
G. Smakman, Hofstra Rinie (1982)
ENERGY-METABOLISM OF PLANTAGO-LANCEOLATA, AS AFFECTED BY CHANGE IN ROOT TEMPERATUREPhysiologia Plantarum, 56
(1981)
Use of Cresyl Fast Violet for Studying of Wood Formation
I. Villenbrink (2002)
Transport of Assimilates in Phloem. Regulation and MechanismFiziol. Rast., 49
N. Parameswaran, W. Liese (1974)
Variation of cell length in bark and wood of tropical treesWood Science and Technology, 8
R. Evert (1977)
Phloem Structure and HistochemistryAnnual Review of Plant Biology, 28
M. Stanzel, R. Sjolund, E. Komor (1988)
Transport of glucose, fructose and sucrose by Streptanthus tortuosus suspension cellsPlanta, 174
L.M. Srivastava, T.P. O’Brien (1966)
On the Ultrastructure of Cambium and Its Vascular Derivatives. 2. Secondary Phloem of Pinus strobus L.Protoplasma, 61
(1984)
Comparative Anatomy of Bark in the Pinaceae
(1958)
Formation of Pine Tracheids
I.N. Elagin (1976)
Sezonnoe rasvitie sosnovykh lesov
A.L. Kursanov (1984)
Endogenous Regulation of Assimilate Transport and Donor-Acceptor Interactions in PlantsFiziol. Rast., 31
(2004)
Involvement of Apoplast in Regulation of Transport of Assimilates, Photosynthesis, and Plant Productivity, Fiziol
K. Ezau (1980)
Anatomiya rastenii
(1983)
A Study of Water Soluble Polysaccharides in Developing Xylem of Scots Pine, Fiziol
(1998)
Photosynthesis and Export of Photosynthates. Development of Transport System and Donor-Acceptor Interactions, Fiziol
J. Zakrzewski (1983)
Hormonal control of cambial activity and vessel differentiation in Quercus roburPhysiologia Plantarum, 57
J. Barnett, J. Harris (1975)
Early stages of bordered pit formation in radiata pineWood Science and Technology, 9
L. Srivastava, T. O'Brien (1966)
On the ultrastructure of cambium and its vascular derivativesProtoplasma, 61
(1989)
Dynamics of Plastic Substances of the Xylem Annual Layer in Pine Shoots
P. Wolswinkel (1985)
Phloem unloading and turgor‐sensitive transport: Factors involved in sink control of assimilate partitioningPhysiologia Plantarum, 65
Structure and Development of Phloem Cells . 1 . Parenchymatous Elements
W.O. Golinowski (1971)
The Anatomical Structure of the Common Fir (Abies alba Mill.) Bark. 1. Development of Bark TissuesActa Soc., Bot. Pol., 40
G.F. Antonova (1999)
Rost kletok khvoinykh
(1970)
Hydrolysis of Sucrose in Free Space of Leaf Tissues and Localization of Invertase, Fiziol
(1982)
Effect of Chilling on Auxin and Abscisic Acid Contents in Millet Plants, Fiziol
(1985)
Application of Gel Chromatography for Studying Metabolites of Developing Xylem in Conifers, Issledovanie metabolizma drevesinnykh rastenii (A Study of Metabolism in Tree Plants)
L. Murmanis, I. Sachs (1969)
Seasonal development of secondary xylem in Pinus Strobus L.Wood Science and Technology, 3
N.E. Sudachkova, N.N. Kozhevnikova, T.G. Lyubarskaya (1980)
Oxidoreductases of Scots Pine Pericambial Zone, Problemy lesnoi biogeotsenologii
M. Stanzel, R.D. Sjolung, E. Komor (1988)
Transport of Glucose, Fructose and Sucrose by Streptantluis tortuosus Suspension Cells. 2. Uptake at High Sugar ConcentrationPlanta, 174
(1956)
Pattern in Meristems of Vascular Plants . 1
(1981)
Photosynthesis and Export of Photosyn - thates
A. Shcherbatyuk, L. Yan’kova, L. Rusakova (1990)
Ecological and physiological features of gas exchange in conifers.Lesovedenie
E. Troeng, S. Linder (1982)
Gas exchange in a 20-year-old stand of Scots pinePhysiologia Plantarum, 54
V.M. Eremin (1984)
Dr. Sci. (Biol.) Dissertation
D. Fry, I. Phillips (1977)
Photosynthesis of Conifers in Relation to Annual Growth Cycles and Dry Matter ProductionPhysiologia Plantarum, 40
M. Caffrey, V. Fonseca, A. Leopold (1988)
Lipid-sugar interactions : relevance to anhydrous biology.Plant physiology, 86 3
Y. Oribe, R. Funada, T. Kubo (2003)
Relationships between cambial activity, cell differentiation and the localization of starch in storage tissues around the cambium in locally heated stems of Abies sachalinensis (Schmidt) MastersTrees, 17
R.F. Evert (1977)
Phloem Structure and HistochemistryAnnu. Rev. Plant Physiol., 28
G.V. Osetrova (1977)
Obmen veshchestv i produktivnost’ khvoinykh
A. Bel (1990)
Xylem-Phloem Exchange Via the Rays: The Undervalued Route of TransportJournal of Experimental Botany, 41
A. Kursanov (1984)
Assimilate transport in plants
N. Kutscha, F. Hyland, J. Schwarzmann (1975)
Certain seasonal changes in balsam fir cambium and its derivativesWood Science and Technology, 9
D.J. Fry, L.D.J. Phillips (1977)
Photosynthesis of Conifers in Relation to Annual Growth Cycles and Dry Matter Production. 2. Seasonal Photosynthetic Capacity and Mesophyll Ultrastructure in Abies grandis, Picea sitchensis, Tsuga heterophylla and Larix leptolepis Growing in S.W. EnglandPhysiol. Plant., 40
L.M. Srivastava (1969)
On the Ultrastructure of Cambium and Its Vascular Derivatives. 3. The Secondary Walls of the Sieve Elements of Pinus strobesAm. J. Bot., 56
R. Savidge (1983)
The role of plant hormones in higher plant cellular differentiation. II. Experiments with the vascular cambium, and sclereid and tracheid differentiation in the pine,Pinus contortaThe Histochemical Journal, 15
A. Catesson, R. Funada, D. Robert-Baby, M. Quinet-Szely, J. Chu-Bâ, R. Goldberg (1994)
Biochemical and Cytochemical Cell Wall Changes Across the Cambial ZoneIawa Journal, 15
G. Antonova, V. Stasova (1993)
Effects of environmental factors on wood formation in Scots pine stemsTrees, 7
R. Riding, C. Little (1984)
Anatomy and histochemistry of Abies balsamea cambial zone cells during the onset and breaking of dormancyBotany, 62
(1992)
Formation of Annual Wood Layer in Stems of Scots Pine and Siberian Larch, Lesovedenie
(1963)
Internal Moisture Stress and Wood Formation in Conifers
V.K. Bolondinskii (1983)
Ekofiziologicheskie issledovaniya fotosinteza i vodnogo regima rastenii v polevykh usloviyakh
Yu.V. Gamalei (2004)
Transportnaya sistema sosudistykh rastenii
J. Sauter (1988)
Temperature-induced Changes in Starch and Sugars in the Stem of Populus × canadensis «robusta»Journal of Plant Physiology, 132
P. SEMENOVAG., V. Sukachev (2007)
The Annual Dynamics of Reserve Compounds and Hydrolitic Enzymes Activity in the Tissues of Pinus sylvestris L. and Larix sibirica Ledeb.:The Metabolism of Reserve Compounds in the Tissues of Siberian Conifers
(2002)
Photosynthetic Productivity of Pinus sylvestris, Picea obovata and Larix sibirica
B. Sundberg, C. Little (1990)
Tracheid production in response to changes in the internal level of indole-3-acetic Acid in 1-year-old shoots of scots pine.Plant physiology, 94 4
(1998)
Transport and Distribution of Assimilates in Pants
M. Dubois, K. Gilles, J. Hamilton, P. Rebers, F. Smith (1956)
Colorimetric Method for Determination of Sugars and Related SubstancesAnalytical Chemistry, 28
L.L. Novitskaya, E.A. Zhitkova, Z.D. Bumagina (1999)
Ultrastructure of Membranes of Sieve Elements in Pine, Fir, and BirchBot. Zh., 84
(1971)
Differences in Bark Microstructure in Firs Occurring on Salkhalin
(1977)
Metabolizm khvoinykh i formirovanie drevesiny (Metabolism of Conifers and Formation of Wood)
A.L. Kursanov (1976)
Transport assimilyatov v rastenii
R. Jeffs, D. Northcote (1967)
The influence of indol-3yl acetic acid and sugar on the pattern of induced differentiation in plant tissue culture.Journal of cell science, 2 1
V.I. Osipov (1977)
Fiziologicheskie i biokhimicheskie metody izucheniya drevesnykh rastenii
J. Wilson, W. Keys, P. Wilson, L. Roberts (1994)
Effects of auxin on the spatial distribution of cell division and xylogenesis in lettuce pith explantsProtoplasma, 183
L.N. Menyailo (1987)
Gormonal’naya regulyatsiya ksilogeneza khvoinykh
(1999)
kletok khvoinykh (Cell Growth in Conifers)
(1963)
Internal Moisture Stress and Wood Formation in Conifers, For
(2002)
Transport of Assimilates in Phloem. Regulation and Mechanism, Fiziol
G. Antonova, V. Cherkashin, V. Stasova, T. Varaksina (1995)
Daily dynamics in xylem cell radial growth of Scots pine (Pinus sylvestris L.)Trees, 10
A. Jennings (1981)
The determination of dihydroxy phenolic compounds in extracts of plant tissues.Analytical biochemistry, 118 2
(1983)
Hydrolysis of Sucrose in Free Space of Leaf Tissues and Localization of Invertase
(1972)
A Correlation of Stem Sugars, Starch and Lipid with Wood Formation in Eastern White Pine, Forest
J. Hansen, E. Beck (1994)
Seasonal changes in the utilization and turnover of assimilation products in 8-year-old Scots pine (Pinus sylvestris L.) treesTrees, 8
(1980)
Anatomiya rastenii (Plant Anatomy)
E. Troeng, S. Linder (1982)
Gas Exchange in a 20-Year-Old Stand of Scots Pine (Net Photosynthesis of Current and One-Year-Old Shoots within and between SeasonsPhysiol. Plant., 56
(1977)
Methods of Analysis of Organic Acids in Tissues of Conifers, Fiziologicheskie i biokhimicheskie metody izucheniya drevesnykh rastenii (Physiological and Biochemical Methods of Studying Tree Plants)
V.P. Kholodova (1978)
Pervichnye mekhanizmy
J. Digby, P. Wareing (1966)
The Effect of Applied Growth Hormones on Cambial Division and the Differentiation of the Cambial DerivativesAnnals of Botany, 30
J. Edelman, T. Jeeeord (1968)
THE MECHANISIM OF FRUCTOSAN METABOLISM IN HIGHER PLANTS AS EXEMPLIFIED IN HELIANTHUS TUBEROSUSNew Phytologist, 67
(1987)
Gormonal’naya regulyatsiya ksilogeneza khvoinykh (Hormonal Regulation of Xylogenesis in Conifers)
(1977)
Dynamics of Carbohydrates in Pericambial Zone of Scots Pine and Siberian Larch during the Period of Vegetation, Obmen veshchestv i produktivnost' khvoinykh (Metabolism and Productivity of Conifers)
N.E. Sudachkova (1977)
Metabolizm khvoinykh i formirovanie drevesiny
Frank Alfieri, R. Evert (1968)
SEASONAL DEVELOPMENT OF THE SECONDARY PHLOEM IN PINUSAmerican Journal of Botany, 55
B. Wilson (1966)
MITOTIC ACTIVITY IN THE CAMBIAL ZONE OF PINUS STROBUSAmerican Journal of Botany, 53
R. Savidge, P. Wareing (1981)
A tracheid-differentiation factor from pine needlesPlanta, 153
(1956)
Pattern in Meristems of Vascular Plants. 1. Cell Partition in Living Apices and in the Cambial Zone in Relation to the Concepts of Initial Cells and Apical Cells
(1977)
Structure and Development of Phloem Cells . 1 . Sieve Elements
A.A. Anisimov, V.N. Gordei, L.N. Olyunina (1981)
Bikhimiya i biofizika transporta veshchestv u rastenii
(1980)
Oxidoreductases of Scots Pine Pericambial Zone, Problemy lesnoi biogeotsenologii (Problems of Forest Biogeocoenology)
R. Savidge (1983)
The role of plant hormones in higher plant cellular differentiation. I. A critiqueThe Histochemical Journal, 15
(2004)
Transportnaya sistema sosudistykh rastenii (Transport System of Vascular Plants)
R.A. Savidge (1983)
The Role of Plant Hormones in Higher Plant Cellular Differentiation. 2. Experiments with Vascular Cambium, Sclereids and Tracheid Differentiation in the PinePinus contorta, Hystochem. J., 15
(1982)
Effect of Chilling on Auxin and Abscisic Acid Contents in Millet Plants
N. Sudachkova, I. Milyutina, L. Romanova, G. Semenova (2004)
The Annual Dynamics of Reserve Compounds and Hydrolitic Enzymes Activity in the Tissues of Pinus sylvestris L. and Larix sibirica Ledeb. - The Metabolism of Reserve Compounds in the Tissues of Siberian Conifers -Eurasian journal of forest research, 7
Reff Omran (1980)
Peroxide Levels and the Activities of Catalase, Peroxidase, and Indoleacetic Acid Oxidase during and after Chilling Cucumber Seedlings.Plant physiology, 65 2
J. Sauter, B. Cleve (1994)
Storage, mobilization and interrelations of starch, sugars, protein and fat in the ray storage tissue of poplar treesTrees, 8
L.I. Lotova (1987)
Anatomiya kory khvoinykh
C. Little, B. Sundberg (1991)
Tracheid production in response to indole-3-acetic acid varies with internode age in Pinus sylvestris stemsTrees, 5
D. Morris (1979)
The effect of temperature on the velocity of exogenous auxin transport in intact chilling-sensitive and chilling-resistant plantsPlanta, 146
(1964)
Contemporary Outlook on the Differentiation of Vascular Tissues
(2002)
Transport and Distribution of Assimilates in Pants. Trends, Approaches, and Methods, Fiziol
(1983)
Characteristic of Secondary Phloem Elements of Scots Pine, Lesn
(1997)
On a Possible Cause of Formation of Structural Anomalies in the Karelian Birch Stem
R. Savidge (1996)
Xylogenesis, Genetic and Environmental Regulation-A Review-Iawa Journal, 17
(1972)
Metody biokhimicheskogo analiza rastenii
R. Savidge (1991)
Seasonal Cambial Activity in Larix laricina Saplings in Relation to Endogenous Indol-3-ylacetic Acid, Sucrose, and ConiferinForest Science, 37
(1978)
Compartmentation of Sugars in Plant Tissues, Rost rastenii. Pervichnye mekhanizmy (Plant Growth
G.F. Antonova, V.V. Shebeko (1985)
Issledovanie metabolizma drevesinnykh rastenii
(1987)
Anatomiya kory khvoinykh (Anatomy of Bark in Conifers)
(1976)
Sezonnoe rasvitie sosnovykh lesov (Seasonal Development of Pine Forests)
The formation of phloem was studied for two years in stems of 50 to 60 year old trees of Scots pine (Pinus sylvestris L.) growing in nature. The development of phloem of the current year begins 10 to 20 days before the xylem formation and is completed with the termination of shoot growth in the end of June. Observations over the seasonal activity of cambium producing sieve cells of phloem and duration of their differentiation as compared to the xylem derivatives of cambium have shown that the maxima of formation of phloem and xylem cells could coincide or not coincide by season, while the activities of their differentiation were always in antiphase. The sieve cells of early phloem were separated from those of late phloem by a layer of tannin-containing cells, which are formed simultaneously with the formation of late xylem cells by the cambium. Seasonal dynamics of accumulation of starch grain in structural elements of the phloem is related to the xylem development. The content of metabolites in differentiating and mature phloem elements, in the cambium zone, and in the xylem cells growing in the radial direction depended on cell specificity, stage of their development, and type of forming wood, early or late, which differ in the cell wall parameters and, hence, requirement of assimilates. Significant differences were described between the content of low molecular weigh carbohydrates, amino acids, organic acids, and phenol compounds using two methods of calculation: per dry weight and per cell.
Russian Journal of Developmental Biology – Springer Journals
Published: Sep 21, 2006
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