Esau's plant anatomy: meristems, cells, and tissues of the plant body: their structure, function, and development
Gespeichert in:
| Vorheriger Titel: | Esau, Katherine Plant anatomy |
|---|---|
| Hauptverfasser: | , |
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Hoboken, NJ [u.a.]
Wiley
2006
|
| Ausgabe: | 3. ed. |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | Früher u.d.T.: Esau, Katherine: Plant anatomy Nebentitel: Plant anatomy |
| ISBN: | 0471738433 9780471738435 |
Internformat
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| 245 | 1 | 0 | |a Esau's plant anatomy |b meristems, cells, and tissues of the plant body: their structure, function, and development |c Raymond Evert and Susan E. Eichhorn |
| 246 | 1 | 3 | |a Plant anatomy |
| 250 | |a 3. ed. | ||
| 264 | 1 | |a Hoboken, NJ [u.a.] |b Wiley |c 2006 | |
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| 500 | |a Früher u.d.T.: Esau, Katherine: Plant anatomy | ||
| 500 | |a Nebentitel: Plant anatomy | ||
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| 650 | 4 | |a Arter | |
| 650 | 4 | |a Billedværk, elektronmikroskopibilleder | |
| 650 | 4 | |a Cell differentiation | |
| 650 | 4 | |a Cell structure | |
| 650 | 4 | |a Cell walls | |
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| 650 | 4 | |a Cellestruktur | |
| 650 | 4 | |a Cellevægge | |
| 650 | 4 | |a Cells | |
| 650 | 4 | |a Crops | |
| 650 | 4 | |a Illustrations | |
| 650 | 4 | |a Meristemer | |
| 650 | 4 | |a Meristems | |
| 650 | 4 | |a Plant anatomy | |
| 650 | 4 | |a Plant developmental stages | |
| 650 | 4 | |a Plant physiology | |
| 650 | 4 | |a Plant tissues | |
| 650 | 4 | |a Planteanatomi | |
| 650 | 4 | |a Plantefysiologi | |
| 650 | 4 | |a Planteudviklingstrin | |
| 650 | 4 | |a Plantevæv | |
| 650 | 4 | |a Species | |
| 650 | 4 | |a Tissues | |
| 650 | 4 | |a Ultrastructure | |
| 650 | 4 | |a Ultrastruktur | |
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Datensatz im Suchindex
| _version_ | 1804135714510602240 |
|---|---|
| adam_text | Contents
Preface ................................................................................... xv
Acknowledgments .......................................................................... xvii
General References.......................................................................... xix
Chapter 1 Structure and Development of the Plant Body—An Overview........................ 1
Internal Organization of the Plant Body .............................................. 3
The Body of a Vascular Plant Is Composed of Three Tissue Systems ..................... 3
Structurally Stem, Leaf, and Root Differ Primarily in the Relative
Distribution of the Vascular and Ground Tissues ..................................... 3
Summary of Types of Cells and Tissues............................................... 6
Development of the Plant Body..................................................... 7
The Body Plan of the Plant Is Established during Embryogenesis ........................ 7
With Germination of the Seed, the Embryo Resumes Growth and Gradually Develops into
an Adult Plant ................................................................. 11
REFERENCES.................................................................... 12
Chapter 2 The Protoplast: Plasma Membrane, Nucleus, and Cytoplasmic Organelles............. 15
Prokaryotic and Eukaryotic Cells.................................................... 16
Cytoplasm ...................................................................... 17
Plasma Membrane................................................................ 19
Nucleus ........................................................................ 22
Cell Cycle ...................................................................... 23
Plastids......................................................................... 25
Chloroplasts Contain Chlorophyll and Carotenoid Pigments ............................ 25
vii
viii I Contents
Chromoplasts Contain Only Carotenoid Pigments .................................... 26
Leucoplasts Are Nonpigmented Plastids ............................................ 28
All Plastids Are Derived Initially from Proplastids .................................... 28
Mitochondria.................................................................... 31
Peroxisomes .................................................................... 33
Vacuoles ....................................................................... 34
Ribosomes...................................................................... 36
REFERENCES.................................................................... 37
Chapter 3 The Protoplast: Endomembrane System, Secretory Pathways, Cytoskeleton,
and Stored Compounds ......................................................... 45
Endomembrane System............................................................ 45
The Endoplasmic Reticulum Is a Continuous, Three-dimensional
Membrane System That Permeates the Entire Cytosol ................................. 45
The Golgi Apparatus Is a Highly Polarized Membrane System Involved in Secretion......... 48
Cytoskeleton .................................................................... 49
Microtubules Are Cylindrical Structures Composed of Tubulin Subunits .................. 49
Actin Filaments Consist of Two Linear Chains of Actin Molecules in the Form of a Helix .... 50
Stored Compounds ............................................................... 52
Starch Develops in the Form of Grains in Plastids .................................... 52
The Site of Protein Body Assembly Depends on Protein Composition .................... 53
Oil Bodies Bud from Smooth ER Membranes by an Oleosin-mediated Process.............. 54
Tannins Typically Occur in Vacuoles but Also Are Found in Cell Walls ................... 55
Crystals of Calcium Oxalate Usually Develop in Vacuoles but
Also Are Found in the Cell Wall and Cuticle......................................... 56
Silica Most Commonly Is Deposited in Cell Walls..................................... 58
REFERENCES.................................................................... 58
Chapter 4 Cell Wall....................................................................... 65
Macromolecular Components of the Cell Wall ......................................... 66
Cellulose Is the Principal Component of Plant Cell Walls .............................. 66
The Cellulose Micronbrils Are Embedded in a Matrix of Noncellulosic Molecules .......... 67
Principal Hemicelluoses ....................................................... 67
Pectins ..................................................................... 68
Proteins .................................................................... 68
Callose Is a Widely Distributed Cell Wall Polysaccharide............................... 69
Lignins Are Phenolic Polymers Deposited Mainly in Cell Walls of Supporting and Conducting
Tissues....................................................................... 69
Cutin and Suberin Are Insoluble Lipid Polymers Found Most
Commonly in the Protective Surface Tissues of the Plant .............................. 71
Cell Wall Layers.................................................................. 71
The Middle Lamella Frequently Is Difficult to Distinguish from the Primary Wall........... 72
The Primary Wall Is Deposited While the Cell Is Increasing in Size ...................... 72
The Secondary Wall Is Deposited inside the Primary Wall Largely, If Not Entirely, after the
Primary Wall Has Stopped Increasing in Surface Area ................................. 72
Pits and Primary Pit-Fields ......................................................... 74
Origin of Cell Wall during Cell Division .............................................. 76
Cytokinesis Occurs by the Formation of a Phragmoplast and Cell Plate................... 76
Initially Callose Is the Principal Cell Wall Polysaccharide Present
in the Developing Cell Plate...................................................... 78
The Preprophase Band Predicts the Plane of the Future Cell Plate ....................... 78
Growth of the Cell Wall........................................................... 80
The Orientation of Cellulose Micronbrils within the Primary Wall Influences the
Direction of Cell Expansion ...................................................... 82
When Considering the Mechanism of Wall Growth, It Is Necessary to Distinguish
between Growth in Surface (Wall Expansion) and Growth in Thickness.................. 83
Contents I ix
Expansion of the Primary Cell Wall.................................................. 83
Cessation of Wall Expansion ....................................................... 84
Intercellular Spaces............................................................... 84
Plasmodesmata .................................................................. 85
Plasmodesmata May Be Classified as Primary or Secondary According to Their Origin....... 85
Plasmodesmata Contain Two Types of Membranes: Plasma Membrane and Desmotubule..... 87
Plasmodesmata Enable Cells to Communicate........................................ 88
The Symplast Undergoes Reorganization throughout the Course of Plant Growth and
Development.................................................................. 90
REFERENCES.................................................................... 91
Chapter 5 Meristems and Differentiation ................................................... 103
Meristems ...................................................................... 103
Classification of Meristems....................................................... 104
A Common Classification of Meristems Is Based on Their Position in the Plant Body ...... 104
Meristems Are Also Classified According to the Nature of
Cells That Give Origin to Their Initial Cells ....................................... 106
Characteristics of Meristematic Cells............................................... 106
Growth Patterns in Meristems .................................................... 107
Meristematic Activity and Plant Growth ............................................ 108
Differentiation................................................................... 110
Terms and Concepts ............................................................ 110
Senescence (Programmed Cell Death).............................................. Ill
Cellular Changes in Differentiation ................................................ 113
A Cytologie Phenomenon Commonly Observed in Differentiating
Cells of Angiosperms Is Endopolyploidy .......................................... 113
One of the Early Visible Changes in Differentiating Tissues Is the
Unequal Increase in Cell Size................................................... 113
Intercellular Adjustment in Differentiating Tissue Involves
Coordinated and Intrusive Growth .............................................. 114
Causal Factors in Differentiation .................................................... 115
Tissue Culture Techniques Have Been Useful for the Determination
of Requirements for Growth and Differentiation ..................................... 115
The Analysis of Genetic Mosaics Can Reveal Patterns of Cell Division
and Cell Fate in Developing Plants ................................................ 117
Gene Technologies Have Dramatically Increased Our Understanding of Plant Development... 117
Polarity Is a Key Component of Biological Pattern Formation and
Is Related to the Phenomenon of Gradients ......................................... 119
Plant Cells Differentiate According to Position ....................................... 119
Plant Hormones.................................................................. 120
Auxins ....................................................................... 121
Cytokinins.................................................................... 122
Ethylene...................................................................... 123
Abscisic Acid.................................................................. 123
Gibberellins................................................................... 123
REFERENCES.................................................................... 123
Chapter 6 Apical Meristems ............................................................... 133
Evolution of the Concept of Apical Organization ....................................... 134
Apical Meristems Originally Were Envisioned as Having a Single Initial Cell ............... 134
The Apical-Cell Theory Was Superseded by the Histogen Theory........................ 134
The Tunica-Corpus Concept of Apical Organization Applies Largely to Angiosperms ........ 135
The Shoot Apices of Most Gymnosperms and Angiosperms Show a Cytohistological
Zonation...................................................................... 136
Inquiries into the Identity of Apical Initials ........................................... 136
Vegetative Shoot Apex ............................................................ 138
x I Contents________________________________________________________________________________________
The Presence of an Apical Cell Is Characteristic of Shoot Apices in Seedless Vascular
Plants ........................................................................ 139
The Zonation Found in the Ginkgo Apex Has Served as a Basis for the Interpretation of
Shoot Apices in Other Gymnosperms .............................................. 140
The Presence of a Zonation Superimposed on a Tunica-Corpus Configuration Is
Characteristic of Angiosperm Shoot Apices.......................................... 141
The Vegetative Shoot Apex of Arabidopsis thaliana.................................... 143
Origin of Leaves ................................................................. 145
Throughout the Vegetative Period the Shoot Apical Meristem Produces Leaves in a
Regular Order ................................................................. 145
The Initiation of a Leaf Primordium Is Associated with an Increase
in the Frequency of Periclinal Divisions at the Initiation Site............................ 147
Leaf Primordia Arise at Sites That Are Correlated with the Phyllotaxis of the Shoot......... 149
Origin of Branches ............................................................... 149
In Most Seed Plants Axillary Meristems Originate from Detached Meristems............... 150
Shoots May Develop from Adventitious Buds ........................................ 152
Root Apex ...................................................................... 152
Apical Organization in Roots May Be either Open or Closed............................ 153
The Quiescent Center Is Not Completely Devoid of Divisions under Normal Conditions ..... 157
The Root Apex of Arabidopsis thaliana.............................................. 160
Growth of the Root Tip............................................................ 162
REFERENCES.................................................................... 165
Chapter 7 Parenchyma and Collenchyma................................................... 175
Parenchyma..................................................................... 175
Parenchyma Cells May Occur in Continuous Masses as Parenchyma Tissue or Be
Associated with Other Cell Types in Morphologically Heterogeneous Tissues.............. 176
The Contents of Parenchyma Cells Are a Reflection of the Activities of the Cells ........... 177
The Cell Walls of Parenchyma Cells May Be Thick or Thin............................. 178
Some Parenchyma Cells—Transfer Cells—Contain Wall Ingrowths....................... 179
Parenchyma Cells Vary Greatly in Shape and Arrangement ............................. 181
Some Parenchyma Tissue—Aerenchyma—Contains Particularly Large Intercellular Spaces ..... 182
Collenchyma .................................................................... 183
The Structure of the Cell Walls of Collenchyma Is the Most Distinctive Characteristic of
This Tissue.................................................................... 184
Collenchyma Characteristically Occurs in a Peripheral Position ......................... 185
Collenchyma Appears to Be Particularly Well Adapted for Support of
Growing Leaves and Stems....................................................... 187
REFERENCES.................................................................... 187
Chapter 8 Sclerenchyma .................................................................. 191
Fibers.......................................................................... 192
Fibers Are Widely Distributed in the Plant Body...................................... 192
Fibers May Be Divided into Two Large Groups, Xylary and Extraxylary................... 194
Both Xylary and Extraxylary Fibers May Be Septate or Gelatinous ....................... 196
Commercial Fibers Are Separated into Soft Fibers and Hard Fibers....................... 197
Sclereids........................................................................ 198
Based on Shape and Size, Sclereids May Be Classified into a Number of Types ............. 198
Sclereids Like Fibers Are Widely Distributed in the Plant Body.......................... 199
Sclereids in Stems ............................................................ 200
Sclereids in Leaves............................................................ 200
Sclereids in Fruits ............................................................ 201
Sclereids in Seeds ............................................................ 201
Origin and Development of Fibers and Sclereids ....................................... 202
Factors Controlling Development of Fibers and Sclereids ................................ 205
REFERENCES.................................................................... 207
_______________________________________________________________________________________Contents | xi
Chapter 9 Epidermis ..................................................................... 211
Ordinary Epidermal Cells.......................................................... 214
Epidermal Cell Walls Vary in Thickness ............................................ 214
The Most Distinctive Feature of the Outer Epidermal Wall Is the Presence of a Cuticle ...... 215
Stomata ........................................................................ 218
Stomata Occur on All Aerial Parts of the Primary Plant Body ........................... 218
Guard Cells Are Generally Kidney-shaped .......................................... 221
Guard Cells Typically Have Unevenly Thickened Walls with Radially Arranged
Cellulose Microfibrils ........................................................... 222
Blue Light and Abscisic Acid Are Important Signals in the Control of
Stomatal Movement............................................................. 224
Development of Stomatal Complexes Involves One or More Asymmetric Cell Divisions...... 225
Different Developmental Sequences Result in Different
Configurations of Stomatal Complexes ............................................. 228
Trichomes ...................................................................... 229
Trichomes Have a Variety of Functions ............................................. 229
Trichomes May Be Classified into Different Morphological Categories .................... 230
A Trichome Is Initiated as a Protuberance from an Epidermal Cell....................... 230
The Cotton Fiber............................................................. 230
Root Hairs .................................................................. 234
The Arabidopsis Trichome..................................................... 235
Cell Patterning in the Epidermis .................................................... 237
The Spatial Distribution of Stomata and Trichomes in Leaves Is Nonrandom............... 237
There Are Three Main Types of Patterning in the Epidermis of Angiosperm Roots.......... 238
Other Specialized Epidermal Cells................................................... 239
Silica and Cork Cells Frequently Occur Together in Pairs .............................. 239
Bulliform Cells Are Highly Vacuolated Cells......................................... 241
Some Epidermal Hairs Contain Cystoliths ........................................... 242
REFERENCES.................................................................... 243
Chapter 10 Xylem: Cell Types and Developmental Aspects..................................... 255
Cell Types of the Xylem ........................................................... 256
Tracheary Elements—Tracheids and Vessel Elements—Are the Conducting Cells of the
Xylem........................................................................ 256
The Secondary Walls of Most Tracheary Elements Contain Pits.......................... 260
Vessels Are More Efficient Conduits of Water Than Are Tracheids........................ 263
Fibers Are Specialized as Supporting Elements in the Xylem............................ 266
Living Parenchyma Cells Occur in Both the Primary and Secondary Xylem................ 266
In Some Species the Parenchyma Cells Develop Protrusions—Tyloses—That Enter the
Vessels ....................................................................... 267
Phylogenetic Specialization of Tracheary Elements and Fibers ............................ 268
The Major Trends in the Evolution of the Vessel Element Are Correlated with Decrease in
Vessel Element Length........................................................... 268
Deviations Exist in Trends of Vessel Element Evolution ................................ 270
Like Vessel Elements and Tracheids, Fibers Have Undergone a Phylogenetic Shortening ..... 271
Primary Xylem................................................................... 271
Some Developmental and Structural Differences Exist between the Earlier and Later Formed
Parts of the Primary Xylem....................................................... 2 71
The Primary Tracheary Elements Have a Variety of Secondary Wall Thickenings ........... 273
Tracheary Element Differentiation................................................... 276
Plant Hormones Are Involved in the Differentiation of Tracheary Elements................ 280
Isolated Mesophyll Cells in Culture Can Transdifferentiate Directly into
Tracheary Elements............................................................. 281
REFERENCES.................................................................... 283
xii I Contents
Chapter 11 Xylem: Secondary Xylem and Variations in Wood Structure 291
Basic Structure of Secondary Xylem ................................................. 293
The Secondary Xylem Consists of Two Distinct Systems of Cells, Axial and Radial.......... 293
Some Woods Are Storied and Others Are Nonstoried.................................. 294
Growth Rings Result from the Periodic Activity of the Vascular Cambium ................ 294
As Wood Becomes Older, It Gradually Becomes Nonfunctional in Conduction and Storage . . . 297
Reaction Wood Is a Type of Wood That Develops in Branches
and Leaning or Crooked Stems.................................................... 299
Woods ......................................................................... 302
The Wood of Conifers Is Relatively Simple in Structure................................ 302
The Axial System of Conifer Woods Consists Mostly or Entirely of Tracheids .............. 302
The Rays of Conifers May Consist of Both Parenchyma Cells and Tracheids ............... 303
The Wood of Many Conifers Contains Resin Ducts ................................... 304
The Wood of Angiosperms Is More Complex and Varied Than That of Conifers............ 306
On the Basis of Porosity, Two Main Types of Angiosperm Wood Are Recognized: Diffuse-
porous and Ring-porous ......................................................... 307
The Distribution of Axial Parenchyma Shows Many Intergrading Patterns................. 309
The Rays of Angiosperms Typically Contain Only Parenchyma Cells ..................... 310
Intercellular Spaces Similar to the Resin Ducts of Gymnosperms
Occur in Angiosperm Woods..................................................... 312
Some Aspects of Secondary Xylem Development ....................................... 312
Identification of Wood ............................................................ 315
REFERENCES.................................................................... 316
Chapter 12 Vascular Cambium.............................................................. 323
Organization of the Cambium ...................................................... 323
The Vascular Cambium Contains Two Types of Initials: Fusiform Initials and Ray Initials .... 323
The Cambium May Be Storied or Nonstoried ........................................ 325
Formation of Secondary Xylem and Secondary Phloem .................................. 326
Initials Versus Their Immediate Derivatives ........................................... 327
Developmental Changes........................................................... 330
Formation of New Ray Initials from Fusiform Initials or Their Segments Is a Common
Phenomenon .................................................................. 332
Domains Can Be Recognized within the Cambium ................................... 335
Seasonal Changes in Cambial Cell Ultrastructure....................................... 336
Cytokinesis of Fusiform Cells....................................................... 338
Seasonal Activity................................................................. 341
The Size of the Xylem Increment Produced during One Year Generally Exceeds That of the
Phloem....................................................................... 343
A Distinct Seasonally in Cambial Activity Also Occurs in Many Tropical Regions........... 344
Causal Relations in Cambial Activity ................................................. 346
REFERENCES.................................................................... 348
Chapter 13 Phloem: Cell Types and Developmental Aspects.................................... 357
Cell Types of the Phloem.......................................................... 359
The Angiospermous Sieve-Tube Element.............................................. 360
In Some Taxa the Sieve-Tube Element Walls Are Remarkably Thick ...................... 36l
Sieve Plates Usually Occur on End Walls............................................ 364
Callose Apparently Plays a Role in Sieve-Pore Development ............................ 364
Changes in the Appearance of the Plastids and the Appearance of P-protein Are Early
Indicators of Sieve-Tube Element Development ...................................... 365
Nuclear Degeneration May Be Chromatolytic or Pycnotic .............................. 372
Companion Cells................................................................. 372
The Mechanism of Phloem Transport in Angiosperms .................................. 379
The Source Leaf and Minor Vein Phloem ............................................. 382
Contents I xiii
Several Types of Minor Veins Occur in Dicotyledonous Leaves.......................... 384
Type 1 Species with Specialized Companion Cells, Termed Intermediary Cells, Are
Symplastic Loaders ............................................................. 384
Species with Type 2 Minor Veins Are Apoplastic Loaders .............................. 385
The Collection of Photoassimitate by the Minor Veins in Some Leaves May Not Involve an
Active Step.................................................................... 385
Some Minor Veins Contain More Than One Kind of Companion Cell..................... 385
The Minor Veins in Leaf Blades of the Poaceae Contain Two Types of Metaphloem Sieve
Tubes ........................................................................ 386
The Gymnospermous Sieve Cell .................................................... 386
The Walls of Sieve Cells Are Characterized as Primary ................................ 387
Callose Does Not Play a Role in Sieve-Pore Development in Gymnosperms................ 387
Little Variation Exists in Sieve-Cell Differentiation among Gymnosperms ................. 388
Strasburger Cells................................................................. 390
The Mechanism of Phloem Transport in Gymnosperms ................................. 390
Parenchyma Cells ................................................................ 391
Sclerenchyma Cells............................................................... 391
Longevity of Sieve Elements........................................................ 391
Trends in Specialization of Sieve-Tube Elements........................................ 392
Sieve Elements of Seedless Vascular Plants ............................................ 393
Primary Phloem ................................................................. 393
REFERENCES.................................................................... 398
Chapter 14 Phloem: Secondary Phloem and Variations in Its Structure.......................... 407
Conifer Phloem.................................................................. 409
Angiosperm Phloem.............................................................. 412
The Patterns Formed by the Fibers Can Be of Taxonomic Significance.................... 413
Secondary Sieve-Tube Elements Show Considerable Variation in Form and Distribution...... 415
Differentiation in the Secondary Phloem.............................................. 417
Sclerenchyma Cells in the Secondary Phloem Commonly Are Classified as Fibers, Sclereids,
and Fiber-Sclereids ............................................................. 418
The Conducting Phloem Constitutes Only a Small Part of the Inner Bark ................. 420
Nonconducting Phloem ........................................................... 422
The Nonconducting Phloem Differs Structurally from the Conducting Phloem............. 423
Dilatation Is the Means by Which the Phloem Is Adjusted to the Increase in Circumference
of the Axis Resulting from Secondary Growth ....................................... 423
REFERENCES.................................................................... 424
Chapter 15 Periderm ...................................................................... 427
Occurrence ..................................................................... 427
Characteristics of the Components .................................................. 429
The Phellogen Is Relatively Simple in Structure ...................................... 429
Several Kinds of Phellem Cells May Arise from the Phellogen........................... 429
Considerable Variation Exists in the Width and Composition of Phelloderm ............... 431
Development of Periderm.......................................................... 433
The Sites of Origin of the Phellogen Are Varied ...................................... 433
The Phellogen Is Initiated by Divisions of Various Kinds of Cells ........................ 434
The Time of Appearance of the First and Subsequent Periderms Varies................... 434
Morphology of Periderm and Rhytidome ............................................. 437
Polyderm....................................................................... 438
Protective Tissue in Monocotyledons ................................................ 438
Wound Periderm................................................................. 438
Lenticels ....................................................................... 440
Three Structural Types of Lenticels Are Recognized in Woody Angiosperms............... 441
The First Lenticels Frequently Appear under Stomata ................................. 442
REFERENCES.................................................................... 442
xiv I Contents
Chapter 16 External Secretory Structures.................................................... 447
Salt Glands......................................................................
Salt Bladders Secrete Ions into a Large Central Vacuole................................ 449
Other Glands Secrete Salt Directly to the Outside .................................... 449
The Two-celled Glands of the Poaceae ........................................... 449
The Multicellular Glands of Eudicotyledons ....................................... 450
Hydathodes ..................................................................... 451
Nectaries....................................................................... 452
The Nectaries of Lonicera japonica Exude Nectar from Unicellular Trichomes ............ 455
The Nectaries of Abutilon striatum Exude Nectar from Multicellular Trichomes........... 456
The Nectaries of Vicia faba Exude Nectar via Stomata ................................ 456
The Most Common Sugars in Nectar Are Sucrose, Glucose, and Fructose ................. 456
Structures Intermediate between Nectaries and Hydathodes Also Exist................... 459
Colleters ....................................................................... 459
Osmophores .................................................................... 461
Glandular Trichomes Secreting Lipophilic Substances................................... 462
Glandular Trichome Development................................................... 463
The Glandular Structures of Carnivorous Plants........................................ 465
Stinging Hairs ................................................................... 466
REFERENCES.................................................................... 466
Chapter 17 Internal Secretory Structures .................................................... 473
Internal Secretory Cells ........................................................... 473
Oil Cells Secrete Their Oils into an Oil Cavity ....................................... 475
Mucilage Cells Deposit Their Mucilage between the Protoplast and the Cellulosic Cell
Wall ......................................................................... 476
Tannin Is the Most Conspicuous Inclusion in Numerous Secretory Cells .................. 477
Secretory Cavities and Ducts ....................................................... 478
The Best-Known Secretory Ducts Are the Resin Ducts of Conifers....................... 478
Development of Secretory Cavities Appears to Be Schizogenous......................... 479
Secretory Ducts and Cavities May Arise under the Stimulus of Injury..................... 481
Kino Veins Are a Special Type of Traumatic Duct .................................... 482
Laticifers ....................................................................... 483
On the Basis of Their Structure, Laticifers Are Grouped in Two Major Classes: Articulated
and Nonarticulated ............................................................. 484
Latex Varies in Appearance and in Composition...................................... 486
Articulated and Nonarticulated Laticifers Apparently Differ from One Another
Cytologically .................................................................. 487
Laticifers Are Widely Distributed in the Plant Body, Reflecting Their Mode of
Development.................................................................. 489
Nonarticulated Laticifers....................................................... 489
Articulated Laticifers.......................................................... 491
The Principal Source of Commercial Rubber Is the Bark of the Para Rubber Tree, Hevea
brasiliensis ..................................................................... 493
The Function of Laticifers Is Not Clear............................................... 495
REFERENCES.................................................................... 495
Addendum: Other Pertinent References Not Cited in the Text ...................................... 503
Glossary.......................................................... 521
Author Index .......................................................... 541
Subject Index ....................................................................
|
| adam_txt |
Contents
Preface . xv
Acknowledgments . xvii
General References. xix
Chapter 1 Structure and Development of the Plant Body—An Overview. 1
Internal Organization of the Plant Body . 3
The Body of a Vascular Plant Is Composed of Three Tissue Systems . 3
Structurally Stem, Leaf, and Root Differ Primarily in the Relative
Distribution of the Vascular and Ground Tissues . 3
Summary of Types of Cells and Tissues. 6
Development of the Plant Body. 7
The Body Plan of the Plant Is Established during Embryogenesis . 7
With Germination of the Seed, the Embryo Resumes Growth and Gradually Develops into
an Adult Plant . 11
REFERENCES. 12
Chapter 2 The Protoplast: Plasma Membrane, Nucleus, and Cytoplasmic Organelles. 15
Prokaryotic and Eukaryotic Cells. 16
Cytoplasm . 17
Plasma Membrane. 19
Nucleus . 22
Cell Cycle . 23
Plastids. 25
Chloroplasts Contain Chlorophyll and Carotenoid Pigments . 25
vii
viii I Contents
Chromoplasts Contain Only Carotenoid Pigments . 26
Leucoplasts Are Nonpigmented Plastids . 28
All Plastids Are Derived Initially from Proplastids . 28
Mitochondria. 31
Peroxisomes . 33
Vacuoles . 34
Ribosomes. 36
REFERENCES. 37
Chapter 3 The Protoplast: Endomembrane System, Secretory Pathways, Cytoskeleton,
and Stored Compounds . 45
Endomembrane System. 45
The Endoplasmic Reticulum Is a Continuous, Three-dimensional
Membrane System That Permeates the Entire Cytosol . 45
The Golgi Apparatus Is a Highly Polarized Membrane System Involved in Secretion. 48
Cytoskeleton . 49
Microtubules Are Cylindrical Structures Composed of Tubulin Subunits . 49
Actin Filaments Consist of Two Linear Chains of Actin Molecules in the Form of a Helix . 50
Stored Compounds . 52
Starch Develops in the Form of Grains in Plastids . 52
The Site of Protein Body Assembly Depends on Protein Composition . 53
Oil Bodies Bud from Smooth ER Membranes by an Oleosin-mediated Process. 54
Tannins Typically Occur in Vacuoles but Also Are Found in Cell Walls . 55
Crystals of Calcium Oxalate Usually Develop in Vacuoles but
Also Are Found in the Cell Wall and Cuticle. 56
Silica Most Commonly Is Deposited in Cell Walls. 58
REFERENCES. 58
Chapter 4 Cell Wall. 65
Macromolecular Components of the Cell Wall . 66
Cellulose Is the Principal Component of Plant Cell Walls . 66
The Cellulose Micronbrils Are Embedded in a Matrix of Noncellulosic Molecules . 67
Principal Hemicelluoses . 67
Pectins . 68
Proteins . 68
Callose Is a Widely Distributed Cell Wall Polysaccharide. 69
Lignins Are Phenolic Polymers Deposited Mainly in Cell Walls of Supporting and Conducting
Tissues. 69
Cutin and Suberin Are Insoluble Lipid Polymers Found Most
Commonly in the Protective Surface Tissues of the Plant . 71
Cell Wall Layers. 71
The Middle Lamella Frequently Is Difficult to Distinguish from the Primary Wall. 72
The Primary Wall Is Deposited While the Cell Is Increasing in Size . 72
The Secondary Wall Is Deposited inside the Primary Wall Largely, If Not Entirely, after the
Primary Wall Has Stopped Increasing in Surface Area . 72
Pits and Primary Pit-Fields . 74
Origin of Cell Wall during Cell Division . 76
Cytokinesis Occurs by the Formation of a Phragmoplast and Cell Plate. 76
Initially Callose Is the Principal Cell Wall Polysaccharide Present
in the Developing Cell Plate. 78
The Preprophase Band Predicts the Plane of the Future Cell Plate . 78
Growth of the Cell Wall. 80
The Orientation of Cellulose Micronbrils within the Primary Wall Influences the
Direction of Cell Expansion . 82
When Considering the Mechanism of Wall Growth, It Is Necessary to Distinguish
between Growth in Surface (Wall Expansion) and Growth in Thickness. 83
Contents I ix
Expansion of the Primary Cell Wall. 83
Cessation of Wall Expansion . 84
Intercellular Spaces. 84
Plasmodesmata . 85
Plasmodesmata May Be Classified as Primary or Secondary According to Their Origin. 85
Plasmodesmata Contain Two Types of Membranes: Plasma Membrane and Desmotubule. 87
Plasmodesmata Enable Cells to Communicate. 88
The Symplast Undergoes Reorganization throughout the Course of Plant Growth and
Development. 90
REFERENCES. 91
Chapter 5 Meristems and Differentiation . 103
Meristems . 103
Classification of Meristems. 104
A Common Classification of Meristems Is Based on Their Position in the Plant Body . 104
Meristems Are Also Classified According to the Nature of
Cells That Give Origin to Their Initial Cells . 106
Characteristics of Meristematic Cells. 106
Growth Patterns in Meristems . 107
Meristematic Activity and Plant Growth . 108
Differentiation. 110
Terms and Concepts . 110
Senescence (Programmed Cell Death). Ill
Cellular Changes in Differentiation . 113
A Cytologie Phenomenon Commonly Observed in Differentiating
Cells of Angiosperms Is Endopolyploidy . 113
One of the Early Visible Changes in Differentiating Tissues Is the
Unequal Increase in Cell Size. 113
Intercellular Adjustment in Differentiating Tissue Involves
Coordinated and Intrusive Growth . 114
Causal Factors in Differentiation . 115
Tissue Culture Techniques Have Been Useful for the Determination
of Requirements for Growth and Differentiation . 115
The Analysis of Genetic Mosaics Can Reveal Patterns of Cell Division
and Cell Fate in Developing Plants . 117
Gene Technologies Have Dramatically Increased Our Understanding of Plant Development. 117
Polarity Is a Key Component of Biological Pattern Formation and
Is Related to the Phenomenon of Gradients . 119
Plant Cells Differentiate According to Position . 119
Plant Hormones. 120
Auxins . 121
Cytokinins. 122
Ethylene. 123
Abscisic Acid. 123
Gibberellins. 123
REFERENCES. 123
Chapter 6 Apical Meristems . 133
Evolution of the Concept of Apical Organization . 134
Apical Meristems Originally Were Envisioned as Having a Single Initial Cell . 134
The Apical-Cell Theory Was Superseded by the Histogen Theory. 134
The Tunica-Corpus Concept of Apical Organization Applies Largely to Angiosperms . 135
The Shoot Apices of Most Gymnosperms and Angiosperms Show a Cytohistological
Zonation. 136
Inquiries into the Identity of Apical Initials . 136
Vegetative Shoot Apex . 138
x I Contents_
The Presence of an Apical Cell Is Characteristic of Shoot Apices in Seedless Vascular
Plants . 139
The Zonation Found in the Ginkgo Apex Has Served as a Basis for the Interpretation of
Shoot Apices in Other Gymnosperms . 140
The Presence of a Zonation Superimposed on a Tunica-Corpus Configuration Is
Characteristic of Angiosperm Shoot Apices. 141
The Vegetative Shoot Apex of Arabidopsis thaliana. 143
Origin of Leaves . 145
Throughout the Vegetative Period the Shoot Apical Meristem Produces Leaves in a
Regular Order . 145
The Initiation of a Leaf Primordium Is Associated with an Increase
in the Frequency of Periclinal Divisions at the Initiation Site. 147
Leaf Primordia Arise at Sites That Are Correlated with the Phyllotaxis of the Shoot. 149
Origin of Branches . 149
In Most Seed Plants Axillary Meristems Originate from Detached Meristems. 150
Shoots May Develop from Adventitious Buds . 152
Root Apex . 152
Apical Organization in Roots May Be either Open or Closed. 153
The Quiescent Center Is Not Completely Devoid of Divisions under Normal Conditions . 157
The Root Apex of Arabidopsis thaliana. 160
Growth of the Root Tip. 162
REFERENCES. 165
Chapter 7 Parenchyma and Collenchyma. 175
Parenchyma. 175
Parenchyma Cells May Occur in Continuous Masses as Parenchyma Tissue or Be
Associated with Other Cell Types in Morphologically Heterogeneous Tissues. 176
The Contents of Parenchyma Cells Are a Reflection of the Activities of the Cells . 177
The Cell Walls of Parenchyma Cells May Be Thick or Thin. 178
Some Parenchyma Cells—Transfer Cells—Contain Wall Ingrowths. 179
Parenchyma Cells Vary Greatly in Shape and Arrangement . 181
Some Parenchyma Tissue—Aerenchyma—Contains Particularly Large Intercellular Spaces . 182
Collenchyma . 183
The Structure of the Cell Walls of Collenchyma Is the Most Distinctive Characteristic of
This Tissue. 184
Collenchyma Characteristically Occurs in a Peripheral Position . 185
Collenchyma Appears to Be Particularly Well Adapted for Support of
Growing Leaves and Stems. 187
REFERENCES. 187
Chapter 8 Sclerenchyma . 191
Fibers. 192
Fibers Are Widely Distributed in the Plant Body. 192
Fibers May Be Divided into Two Large Groups, Xylary and Extraxylary. 194
Both Xylary and Extraxylary Fibers May Be Septate or Gelatinous . 196
Commercial Fibers Are Separated into Soft Fibers and Hard Fibers. 197
Sclereids. 198
Based on Shape and Size, Sclereids May Be Classified into a Number of Types . 198
Sclereids Like Fibers Are Widely Distributed in the Plant Body. 199
Sclereids in Stems . 200
Sclereids in Leaves. 200
Sclereids in Fruits . 201
Sclereids in Seeds . 201
Origin and Development of Fibers and Sclereids . 202
Factors Controlling Development of Fibers and Sclereids . 205
REFERENCES. 207
_Contents | xi
Chapter 9 Epidermis . 211
Ordinary Epidermal Cells. 214
Epidermal Cell Walls Vary in Thickness . 214
The Most Distinctive Feature of the Outer Epidermal Wall Is the Presence of a Cuticle . 215
Stomata . 218
Stomata Occur on All Aerial Parts of the Primary Plant Body . 218
Guard Cells Are Generally Kidney-shaped . 221
Guard Cells Typically Have Unevenly Thickened Walls with Radially Arranged
Cellulose Microfibrils . 222
Blue Light and Abscisic Acid Are Important Signals in the Control of
Stomatal Movement. 224
Development of Stomatal Complexes Involves One or More Asymmetric Cell Divisions. 225
Different Developmental Sequences Result in Different
Configurations of Stomatal Complexes . 228
Trichomes . 229
Trichomes Have a Variety of Functions . 229
Trichomes May Be Classified into Different Morphological Categories . 230
A Trichome Is Initiated as a Protuberance from an Epidermal Cell. 230
The Cotton Fiber. 230
Root Hairs . 234
The Arabidopsis Trichome. 235
Cell Patterning in the Epidermis . 237
The Spatial Distribution of Stomata and Trichomes in Leaves Is Nonrandom. 237
There Are Three Main Types of Patterning in the Epidermis of Angiosperm Roots. 238
Other Specialized Epidermal Cells. 239
Silica and Cork Cells Frequently Occur Together in Pairs . 239
Bulliform Cells Are Highly Vacuolated Cells. 241
Some Epidermal Hairs Contain Cystoliths . 242
REFERENCES. 243
Chapter 10 Xylem: Cell Types and Developmental Aspects. 255
Cell Types of the Xylem . 256
Tracheary Elements—Tracheids and Vessel Elements—Are the Conducting Cells of the
Xylem. 256
The Secondary Walls of Most Tracheary Elements Contain Pits. 260
Vessels Are More Efficient Conduits of Water Than Are Tracheids. 263
Fibers Are Specialized as Supporting Elements in the Xylem. 266
Living Parenchyma Cells Occur in Both the Primary and Secondary Xylem. 266
In Some Species the Parenchyma Cells Develop Protrusions—Tyloses—That Enter the
Vessels . 267
Phylogenetic Specialization of Tracheary Elements and Fibers . 268
The Major Trends in the Evolution of the Vessel Element Are Correlated with Decrease in
Vessel Element Length. 268
Deviations Exist in Trends of Vessel Element Evolution . 270
Like Vessel Elements and Tracheids, Fibers Have Undergone a Phylogenetic Shortening . 271
Primary Xylem. 271
Some Developmental and Structural Differences Exist between the Earlier and Later Formed
Parts of the Primary Xylem. 2'71
The Primary Tracheary Elements Have a Variety of Secondary Wall Thickenings . 273
Tracheary Element Differentiation. 276
Plant Hormones Are Involved in the Differentiation of Tracheary Elements. 280
Isolated Mesophyll Cells in Culture Can Transdifferentiate Directly into
Tracheary Elements. 281
REFERENCES. 283
xii I Contents
Chapter 11 Xylem: Secondary Xylem and Variations in Wood Structure 291
Basic Structure of Secondary Xylem . 293
The Secondary Xylem Consists of Two Distinct Systems of Cells, Axial and Radial. 293
Some Woods Are Storied and Others Are Nonstoried. 294
Growth Rings Result from the Periodic Activity of the Vascular Cambium . 294
As Wood Becomes Older, It Gradually Becomes Nonfunctional in Conduction and Storage . . . 297
Reaction Wood Is a Type of Wood That Develops in Branches
and Leaning or Crooked Stems. 299
Woods . 302
The Wood of Conifers Is Relatively Simple in Structure. 302
The Axial System of Conifer Woods Consists Mostly or Entirely of Tracheids . 302
The Rays of Conifers May Consist of Both Parenchyma Cells and Tracheids . 303
The Wood of Many Conifers Contains Resin Ducts . 304
The Wood of Angiosperms Is More Complex and Varied Than That of Conifers. 306
On the Basis of Porosity, Two Main Types of Angiosperm Wood Are Recognized: Diffuse-
porous and Ring-porous . 307
The Distribution of Axial Parenchyma Shows Many Intergrading Patterns. 309
The Rays of Angiosperms Typically Contain Only Parenchyma Cells . 310
Intercellular Spaces Similar to the Resin Ducts of Gymnosperms
Occur in Angiosperm Woods. 312
Some Aspects of Secondary Xylem Development . 312
Identification of Wood . 315
REFERENCES. 316
Chapter 12 Vascular Cambium. 323
Organization of the Cambium . 323
The Vascular Cambium Contains Two Types of Initials: Fusiform Initials and Ray Initials . 323
The Cambium May Be Storied or Nonstoried . 325
Formation of Secondary Xylem and Secondary Phloem . 326
Initials Versus Their Immediate Derivatives . 327
Developmental Changes. 330
Formation of New Ray Initials from Fusiform Initials or Their Segments Is a Common
Phenomenon . 332
Domains Can Be Recognized within the Cambium . 335
Seasonal Changes in Cambial Cell Ultrastructure. 336
Cytokinesis of Fusiform Cells. 338
Seasonal Activity. 341
The Size of the Xylem Increment Produced during One Year Generally Exceeds That of the
Phloem. 343
A Distinct Seasonally in Cambial Activity Also Occurs in Many Tropical Regions. 344
Causal Relations in Cambial Activity . 346
REFERENCES. 348
Chapter 13 Phloem: Cell Types and Developmental Aspects. 357
Cell Types of the Phloem. 359
The Angiospermous Sieve-Tube Element. 360
In Some Taxa the Sieve-Tube Element Walls Are Remarkably Thick . 36l
Sieve Plates Usually Occur on End Walls. 364
Callose Apparently Plays a Role in Sieve-Pore Development . 364
Changes in the Appearance of the Plastids and the Appearance of P-protein Are Early
Indicators of Sieve-Tube Element Development . 365
Nuclear Degeneration May Be Chromatolytic or Pycnotic . 372
Companion Cells. 372
The Mechanism of Phloem Transport in Angiosperms . 379
The Source Leaf and Minor Vein Phloem . 382
Contents I xiii
Several Types of Minor Veins Occur in Dicotyledonous Leaves. 384
Type 1 Species with Specialized Companion Cells, Termed Intermediary Cells, Are
Symplastic Loaders . 384
Species with Type 2 Minor Veins Are Apoplastic Loaders . 385
The Collection of Photoassimitate by the Minor Veins in Some Leaves May Not Involve an
Active Step. 385
Some Minor Veins Contain More Than One Kind of Companion Cell. 385
The Minor Veins in Leaf Blades of the Poaceae Contain Two Types of Metaphloem Sieve
Tubes . 386
The Gymnospermous Sieve Cell . 386
The Walls of Sieve Cells Are Characterized as Primary . 387
Callose Does Not Play a Role in Sieve-Pore Development in Gymnosperms. 387
Little Variation Exists in Sieve-Cell Differentiation among Gymnosperms . 388
Strasburger Cells. 390
The Mechanism of Phloem Transport in Gymnosperms . 390
Parenchyma Cells . 391
Sclerenchyma Cells. 391
Longevity of Sieve Elements. 391
Trends in Specialization of Sieve-Tube Elements. 392
Sieve Elements of Seedless Vascular Plants . 393
Primary Phloem . 393
REFERENCES. 398
Chapter 14 Phloem: Secondary Phloem and Variations in Its Structure. 407
Conifer Phloem. 409
Angiosperm Phloem. 412
The Patterns Formed by the Fibers Can Be of Taxonomic Significance. 413
Secondary Sieve-Tube Elements Show Considerable Variation in Form and Distribution. 415
Differentiation in the Secondary Phloem. 417
Sclerenchyma Cells in the Secondary Phloem Commonly Are Classified as Fibers, Sclereids,
and Fiber-Sclereids . 418
The Conducting Phloem Constitutes Only a Small Part of the Inner Bark . 420
Nonconducting Phloem . 422
The Nonconducting Phloem Differs Structurally from the Conducting Phloem. 423
Dilatation Is the Means by Which the Phloem Is Adjusted to the Increase in Circumference
of the Axis Resulting from Secondary Growth . 423
REFERENCES. 424
Chapter 15 Periderm . 427
Occurrence . 427
Characteristics of the Components . 429
The Phellogen Is Relatively Simple in Structure . 429
Several Kinds of Phellem Cells May Arise from the Phellogen. 429
Considerable Variation Exists in the Width and Composition of Phelloderm . 431
Development of Periderm. 433
The Sites of Origin of the Phellogen Are Varied . 433
The Phellogen Is Initiated by Divisions of Various Kinds of Cells . 434
The Time of Appearance of the First and Subsequent Periderms Varies. 434
Morphology of Periderm and Rhytidome . 437
Polyderm. 438
Protective Tissue in Monocotyledons . 438
Wound Periderm. 438
Lenticels . 440
Three Structural Types of Lenticels Are Recognized in Woody Angiosperms. 441
The First Lenticels Frequently Appear under Stomata . 442
REFERENCES. 442
xiv I Contents
Chapter 16 External Secretory Structures. 447
Salt Glands.
Salt Bladders Secrete Ions into a Large Central Vacuole. 449
Other Glands Secrete Salt Directly to the Outside . 449
The Two-celled Glands of the Poaceae . 449
The Multicellular Glands of Eudicotyledons . 450
Hydathodes . 451
Nectaries. 452
The Nectaries of Lonicera japonica Exude Nectar from Unicellular Trichomes . 455
The Nectaries of Abutilon striatum Exude Nectar from Multicellular Trichomes. 456
The Nectaries of Vicia faba Exude Nectar via Stomata . 456
The Most Common Sugars in Nectar Are Sucrose, Glucose, and Fructose . 456
Structures Intermediate between Nectaries and Hydathodes Also Exist. 459
Colleters . 459
Osmophores . 461
Glandular Trichomes Secreting Lipophilic Substances. 462
Glandular Trichome Development. 463
The Glandular Structures of Carnivorous Plants. 465
Stinging Hairs . 466
REFERENCES. 466
Chapter 17 Internal Secretory Structures . 473
Internal Secretory Cells . 473
Oil Cells Secrete Their Oils into an Oil Cavity . 475
Mucilage Cells Deposit Their Mucilage between the Protoplast and the Cellulosic Cell
Wall . 476
Tannin Is the Most Conspicuous Inclusion in Numerous Secretory Cells . 477
Secretory Cavities and Ducts . 478
The Best-Known Secretory Ducts Are the Resin Ducts of Conifers. 478
Development of Secretory Cavities Appears to Be Schizogenous. 479
Secretory Ducts and Cavities May Arise under the Stimulus of Injury. 481
Kino Veins Are a Special Type of Traumatic Duct . 482
Laticifers . 483
On the Basis of Their Structure, Laticifers Are Grouped in Two Major Classes: Articulated
and Nonarticulated . 484
Latex Varies in Appearance and in Composition. 486
Articulated and Nonarticulated Laticifers Apparently Differ from One Another
Cytologically . 487
Laticifers Are Widely Distributed in the Plant Body, Reflecting Their Mode of
Development. 489
Nonarticulated Laticifers. 489
Articulated Laticifers. 491
The Principal Source of Commercial Rubber Is the Bark of the Para Rubber Tree, Hevea
brasiliensis . 493
The Function of Laticifers Is Not Clear. 495
REFERENCES. 495
Addendum: Other Pertinent References Not Cited in the Text . 503
Glossary. 521
Author Index . 541
Subject Index . |
| any_adam_object | 1 |
| any_adam_object_boolean | 1 |
| author | Evert, Raymond Eichhorn, Susan E. |
| author_GND | (DE-588)141460784 |
| author_facet | Evert, Raymond Eichhorn, Susan E. |
| author_role | aut aut |
| author_sort | Evert, Raymond |
| author_variant | r e re s e e se see |
| building | Verbundindex |
| bvnumber | BV021799645 |
| classification_tum | BIO 465f |
| ctrlnum | (OCoLC)476676847 (DE-599)BVBBV021799645 |
| discipline | Biologie |
| discipline_str_mv | Biologie |
| edition | 3. ed. |
| format | Book |
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| genre | 1\p (DE-588)4123623-3 Lehrbuch gnd-content |
| genre_facet | Lehrbuch |
| id | DE-604.BV021799645 |
| illustrated | Not Illustrated |
| index_date | 2024-07-02T15:47:24Z |
| indexdate | 2024-07-09T20:44:54Z |
| institution | BVB |
| isbn | 0471738433 9780471738435 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-015012171 |
| oclc_num | 476676847 |
| open_access_boolean | |
| owner | DE-M49 DE-BY-TUM DE-188 DE-20 |
| owner_facet | DE-M49 DE-BY-TUM DE-188 DE-20 |
| publishDate | 2006 |
| publishDateSearch | 2006 |
| publishDateSort | 2006 |
| publisher | Wiley |
| record_format | marc |
| spelling | Evert, Raymond Verfasser aut Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development Raymond Evert and Susan E. Eichhorn Plant anatomy 3. ed. Hoboken, NJ [u.a.] Wiley 2006 txt rdacontent n rdamedia nc rdacarrier Früher u.d.T.: Esau, Katherine: Plant anatomy Nebentitel: Plant anatomy Afgrøder Arter Billedværk, elektronmikroskopibilleder Cell differentiation Cell structure Cell walls Celledifferentiering Celler Cellestruktur Cellevægge Cells Crops Illustrations Meristemer Meristems Plant developmental stages Plant physiology Plant tissues Planteanatomi Plantefysiologi Planteudviklingstrin Plantevæv Species Tissues Ultrastructure Ultrastruktur Væv Histologie (DE-588)4025092-1 gnd rswk-swf Organell (DE-588)4043772-3 gnd rswk-swf Pflanzen (DE-588)4045539-7 gnd rswk-swf Pflanzengewebe (DE-588)4174061-0 gnd rswk-swf Pflanzenanatomie (DE-588)4045543-9 gnd rswk-swf 1\p (DE-588)4123623-3 Lehrbuch gnd-content Pflanzenanatomie (DE-588)4045543-9 s DE-604 Pflanzen (DE-588)4045539-7 s Organell (DE-588)4043772-3 s Histologie (DE-588)4025092-1 s Pflanzengewebe (DE-588)4174061-0 s b DE-604 Eichhorn, Susan E. Verfasser (DE-588)141460784 aut Früher u.d.T. Esau, Katherine Plant anatomy HBZ Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015012171&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk |
| spellingShingle | Evert, Raymond Eichhorn, Susan E. Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development Afgrøder Arter Billedværk, elektronmikroskopibilleder Cell differentiation Cell structure Cell walls Celledifferentiering Celler Cellestruktur Cellevægge Cells Crops Illustrations Meristemer Meristems Plant anatomy Plant developmental stages Plant physiology Plant tissues Planteanatomi Plantefysiologi Planteudviklingstrin Plantevæv Species Tissues Ultrastructure Ultrastruktur Væv Histologie (DE-588)4025092-1 gnd Organell (DE-588)4043772-3 gnd Pflanzen (DE-588)4045539-7 gnd Pflanzengewebe (DE-588)4174061-0 gnd Pflanzenanatomie (DE-588)4045543-9 gnd |
| subject_GND | (DE-588)4025092-1 (DE-588)4043772-3 (DE-588)4045539-7 (DE-588)4174061-0 (DE-588)4045543-9 (DE-588)4123623-3 |
| title | Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development |
| title_alt | Plant anatomy |
| title_auth | Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development |
| title_exact_search | Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development |
| title_exact_search_txtP | Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development |
| title_full | Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development Raymond Evert and Susan E. Eichhorn |
| title_fullStr | Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development Raymond Evert and Susan E. Eichhorn |
| title_full_unstemmed | Esau's plant anatomy meristems, cells, and tissues of the plant body: their structure, function, and development Raymond Evert and Susan E. Eichhorn |
| title_old | Esau, Katherine Plant anatomy |
| title_short | Esau's plant anatomy |
| title_sort | esau s plant anatomy meristems cells and tissues of the plant body their structure function and development |
| title_sub | meristems, cells, and tissues of the plant body: their structure, function, and development |
| topic | Afgrøder Arter Billedværk, elektronmikroskopibilleder Cell differentiation Cell structure Cell walls Celledifferentiering Celler Cellestruktur Cellevægge Cells Crops Illustrations Meristemer Meristems Plant anatomy Plant developmental stages Plant physiology Plant tissues Planteanatomi Plantefysiologi Planteudviklingstrin Plantevæv Species Tissues Ultrastructure Ultrastruktur Væv Histologie (DE-588)4025092-1 gnd Organell (DE-588)4043772-3 gnd Pflanzen (DE-588)4045539-7 gnd Pflanzengewebe (DE-588)4174061-0 gnd Pflanzenanatomie (DE-588)4045543-9 gnd |
| topic_facet | Afgrøder Arter Billedværk, elektronmikroskopibilleder Cell differentiation Cell structure Cell walls Celledifferentiering Celler Cellestruktur Cellevægge Cells Crops Illustrations Meristemer Meristems Plant anatomy Plant developmental stages Plant physiology Plant tissues Planteanatomi Plantefysiologi Planteudviklingstrin Plantevæv Species Tissues Ultrastructure Ultrastruktur Væv Histologie Organell Pflanzen Pflanzengewebe Pflanzenanatomie Lehrbuch |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=015012171&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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