Plant surface microbiology:
Gespeichert in:
| Format: | Buch |
|---|---|
| Sprache: | English |
| Veröffentlicht: |
Berlin [u.a.]
Springer
2008
|
| Ausgabe: | [Taschenbuch-Ausg.] |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XXXI, 628 S. Ill., graph. Dars. |
| ISBN: | 9783540740506 |
Internformat
MARC
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| 245 | 1 | 0 | |a Plant surface microbiology |c Ajit Varma ... (eds.) |
| 250 | |a [Taschenbuch-Ausg.] | ||
| 264 | 1 | |a Berlin [u.a.] |b Springer |c 2008 | |
| 300 | |a XXXI, 628 S. |b Ill., graph. Dars. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 4 | |a Plant surfaces |x Microbiology | |
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| 999 | |a oai:aleph.bib-bvb.de:BVB01-016676967 | ||
Datensatz im Suchindex
| _version_ | 1804137927004913664 |
|---|---|
| adam_text | Contents
The State
of the Art
...................
AjiT
Varma, Lynette K.
Abbott, Dietrich Werner
and
Rüdiger Hampp
Section A
2
Root Colonisation Following Seed Inoculation
....... 13
Thomas EC. Chin-A-Woeng and Ben J.J. Lugtenberg
1
Introduction
........................... 13
2
Bacterial Root Colonisation
.................. 13
3
Analysis of Tomato Root Tip Colonisation
After Seed Inoculation Using a Gnotobiotic Assay
...... 14
3.1
Description of the Gnotobiotic System
............ 14
3.2
Seed Disinfection
........................ 15
3.3
Growth and Preparation of Bacteria
.............. 16
3.4
Seed Inoculation
........................ 17
3.5
Analysis of the Tomato Root Tip
................ 17
3.6
Confocal Laser Scanning Microscopy
............. 18
4
Genetic Tools for Studying Root Colonisation
........ 18
4.1
Marking and Selecting Bacteria
................ 18
4.2
Rhizosphere-Stable Plasmids
................. 21
4.3
Genetic and Metabolic Burdens
................ 21
5
Behaviour of Root-Colonising
Pseudomonas Bacteria in a Gnotobiotic System
....... 22
5.1
Colonisation Strategies of Bacteria
.............. 22
5.2
Competitive Colonisation Studies
............... 23
5.3
Monocots versus Dicots
..................... 25
6
Influence of Abiotic and Biotic Factors
............ 25
VIII Contents
6.1
Abiotic
Factors
......................... 25
6.2
Biotic Factors
.......................... 27
7
Conclusions
........................... 28
References and Selected Reading
..................... 28
3
Methanogenic Microbial Communities Associated
with Aquatic Plants
....................... 35
Ralf Conrad
1
Introduction
........................... 35
2
Role of Plants in Emission of CH4 to the Atmosphere
.... 35
3
Role of Photosynthates and Plant Debris for CH4 Production
38
4
Methanogenic Microbial Communities on Plant Debris
... 40
5
Methanogenic Microbial Communities on Roots
....... 42
6
Interaction of
Methanogens
and Methanotrophs
....... 44
References and Selected Reading
..................... 45
4
Role of Functional Groups of Microorganisms
on the Rhizosphere Microcosm Dynamics
.......... 51
Galdino
Andrade
1
Introduction
........................... 51
2
General Aspects of Functional Groups
of Soil Microorganisms
..................... 52
3
Carbon Cycle Functional Groups
............... 53
4
Functional Groups of Microorganisms of the Nitrogen Cycle
55
5
Functional Groups of Microorganisms of the Sulphur Cycle
57
6
Functional Groups of Microorganisms
of the Phosphorus Cycle
.................... 59
7
Dynamics of the Rhizosphere Functional Groups
of Microorganisms
....................... 60
8
Relationship Among
r
and
к
Strategist Functional Groups
. 61
9
Arbuscular Mycorrhizal
Fungi Dynamics
in the Rhizosphere
....................... 61
10
Dynamics Among the Functional Micro-Organism Groups
of the Carbon, Nitrogen, Phosphorus and Sulphur Cycles
. . 65
References and Selected Reading
..................... 68
Contents
IX
5
Diversity and Functions of Soil
Microflora
in Development of Plants
.................... 71
Ramesh CHandER Kuhad, David Manohar Kothamasi,
K.K. Tripathi and Ajay Singh
1
Introduction
........................... 71
2
Functional Diversity of Soil
Microflora
............ 72
3
Role of Soil
Microflora in
Plant Development
........ 76
3.1
Mycorrhiza
............................ 76
3.2
Actinorhiza
........................... 80
3.3
Plant Growth-Promoting Rhizobacteria
........... 82
3.4
Phosphate-Solubilizing Microorganisms
........... 84
3.5
Lignocellulolytic Microorganisms
............... 85
4
Plant Growth Promoting Substances Produced
by Soil Microbes
......................... 88
5
Conclusions
........................... 90
References and Selected Reading
..................... 91
6
Signalling in the Rhizobia-Legumes Symbiosis
....... 99
Dietrich Werner
1
Introduction
........................... 99
2
The Signals from the Host Plants
............... 101
2.1
Phenylpropanoids: Simple Phenolics, Flavonoids
and Isoflavonoids
........................ 102
2.2
Metabolization of Flavonoids and Isoflavonoids
....... 104
2.3
Vitamins as Growth Factors and Signal Molecules
...... 106
3
Signals from the Microsymbionts
............... 107
3.1
Nod Factors
........................... 107
3.2
Cyclic Glucans
.......................... 109
3.3
Lipopolysaccharides
...................... 110
3.4
Exopolysaccharides
....................... 110
4
Signal Perception and Molecular Biology
of Nodule Initiation
.......................
Ill
References and Selected Reading
..................... 114
X
Contents
Section
В
7
The Functional Groups of Micro-organisms Used
as Bio-indicator on Soil Disturbance Caused
by Biotech Products such as Bacillus thuringiensis
and Bt Transgenic Plants
.................... 121
Galdino
Andrade
1
Introduction
........................... 121
2
General Aspects of Bacillus thuringiensis
........... 122
3
Survival in the Soil
....................... 123
4
History of Bacillus thuringiensis-Tramgmic Plants
..... 124
5
Persistence of the Protein Crystal in the Soil
......... 125
6
Effect of Bacillus thuringiensis and Its Bio-insecticide
Protein on Functional Soil Microorganism Assemblage
. . . 126
References and Selected Reading
..................... 130
8
The Use of ACC Deaminase-Containing
Plant Growth-Promoting Bacteria to Protect Plants
Against the Deleterious Effects of
Ethylene
......... 133
Bernard R. Glick and Donna M. Penrose
1
Introduction
........................... 133
2
Ethylene
............................. 134
3
ACCDeaminase
......................... 135
3.1
Treatment of Plants with ACC Deaminase
Containing Bacteria
....................... 137
4
Conclusions
........................... 140
References and Selected Reading
..................... 141
9
Interactions Between Epiphyllic Microorganisms
and Leaf Cuticles
........................ 145
Lukas Schreiber,
Ursula Krimm and Daniel Knoll
1
Introduction
........................... 145
2
Physical and Chemical Parameters of the Phyllosphere
... 147
3
Leaf Surface Colonisation and Species Composition
..... 149
4
Alteration of Leaf Surface Wetting
............... 150
5
Interaction of Bacteria with Isolated Plant Cuticles
..... 152
6
Conclusions
........................... 153
References and Selected Reading
..................... 154
Contents
XI
10
Developmental Interactions Between Clavidpitaleans
and Their Host Plants
..................... 157
James
E
White Jr., Faith
Belanger, Raymond
Sullivan,
Elizabeth Lewis,
Melinda
Μου,
William Meyer
and Charles W. Bacon
1
Introduction
........................... 157
2
Endophyte/Epibiont Niche
................... 157
3
Coevolution of Clavicipitalean Fungi with Grass Hosts
. . . 158
4
The Jump from Insects to Plants
................ 158
4.1
Trans-Kingdom Jump
...................... 158
4.2
Intermediate Stages in the Transition to Plants
........ 158
4.3
Parasitism of Grass Meristematic Tissues
........... 160
5
Developmental Differentiation of Endophytic
and Epiphyllous Mycelium
................... 160
5.1
Plant Cell Wall Alteration
.................... 160
5.2
Endophytic Mycelial Growth
.................. 160
5.3
Control of Endophytic Mycelial Development
........ 163
5.4
Epiphyllous Mycelial Development
.............. 163
5.5
Expression of Fungal Secreted Hydrolytic
Enzymes in Infected Plants
................... 164
6
Modifications of Plant Tissues for Nutrient Acquisition
. . . 165
6.1
Development of the
Stroma
in
Epichloë
............ 165
6.2
Stroma
Development in Myriogenospora
........... 166
6.3
Mechanisms for Modifying Plant Tissues
........... 168
6.4
Evaporative-Flow Mechanism for Nutrient Acquisition
. . . 169
6.5
The Cytokinin Induction Hypothesis
............. 169
7
Evolution of Asexual Derivatives of
Epichloë
......... 171
7.1
Reproduction and Loss of Sexual Reproduction
....... 171
7.2
The Hypotheses
......................... 172
7.3
The Process of
Stroma
Development and its Loss
...... 173
7.4
The Shift from Pathogen to Mutualist
............. 174
8
Conclusions
........................... 174
References and Selected Reading
..................... 174
11
Interactions of Microbes with Genetically Modified Plants
. 179
Michael Kaldorp, Chi Zhang,
Uwe Nehls,
Rüdiger Hampp
and
François Buscot
1
Introduction
........................... 179
2
Changes in Microbial Communities Induced
by Genetically Modified Plants
................. 181
XII Contents
3
Impact of Genetically Modified Plants
on Symbiotic Interactions
................... 184
4
Horizontal Gene Transfer
.................... 186
5
Conclusions
........................... 191
References and Selected Reading
..................... 192
Section
С
12
Interaction Between Soil Bacteria
and Ectomycorrhiza-Forming Fungi
............. 197
Rüdiger Hampp
and AndREAS Maier
1
Introduction
........................... 197
2
Bacteria
............................. 198
3
Bacterial Community Structure
................ 198
4
Association of Bacteria with Fungal/Ectomycorrhizal
Structures
............................ 199
5
Bacteria Associated with Sporocarps and Ectomycorrhiza
. 200
6
Benefits from Bacteria/Ectomycorrhiza Interactions
.... 201
7
Possible Mechanisms of Interaction
.............. 202
8
Biochemical Evidence for Interaction
............. 203
9
Impacts of Environmental Pollution
.............. 206
10
Conclusions
........................... 206
References and Selected Reading
..................... 207
13
The Surface of Ectomycorrhizal Roots and the
Interaction with Ectomycorrhizal Fungi
........... 211
Ingrid Kottke
1
Introduction
........................... 211
2
Long and Short Roots of Ectomycorrhiza-Forming Plants
. 212
3
A Cuticle-Like Layer on the Surface of Short Roots
..... 214
4
Involvement of the Cuticle-Like Layer
in Mycorrhiza Formation
.................... 218
5
Involvement of the Cuticle-Like Layer in Hyphal Attachment
218
6
Digestion of the Suberin Layer and the Cell Wall
of the Root Cap
......................... 220
7
Hartig
Net Formation
...................... 221
8
Pectins in the Cortical Cell Walls of Nonmycorrhizal
Long and Mycorrhizal Short Roots
.............. 222
9
Conclusions
........................... 223
References and Selected Reading
..................... 224
Contents XIII
14
Cellular Ustilaginomycete
—
Plant Interactions
....... 227
Robert Bauer and Franz Oberwinkler
1
Introduction
........................... 227
2
The Term Smut Fungus
..................... 227
3
Life Cycle
............................. 228
4
Hosts
............................... 228
5
Cellular Interactions
...................... 229
5.1
Local Interaction Zones
..................... 230
5.2
Enlarged Interaction Zones
.................. 234
6
Conclusions
........................... 235
References and Selected Reading
..................... 236
15
Interaction of Piriformospora
indica
with Diverse Microorganisms and Plants
........... 237
Giang Huong Pham, Anjana Singh, Rajani
Malla,
Rina Kumari,
,
Ram
Prasad, Minu
Sachdev,
Karl-Heinz Rexer, Gerhard Kost, Patricia
Luis,
Michael Kaldorf,
François Buscot, Sylvie
Herrmann,
Tanja Peskan, Ralf Oelmüller,
Anil Kumar Saxena,
Stephane Declerck, Maria Mittag, Edith Stabentheiner,
Solveig
Hehl
and Ajit
Varma
1
Introduction
........................... 237
2
Interaction with Microorganisms
............... 238
2.1
Rhizobacteria
.......................... 238
2.2
Chlamydomonas reinhardtii
.................. 239
2.3
Sebacina vermifera
....................... 239
2.4
Other Soil Fungi
......................... 240
2.5
Gaeumannomyces graminis
.................. 240
3
Interaction with Bryophyte
................... 242
4
Interaction with Higher Plants
................. 242
4.1
Monocots
............................ 245
4.2
Legumes
............................. 245
4.3
Orchids
.............................. 246
4.4
Medicinal Plants
......................... 247
4.5
Economically Important Plants
................ 249
4.6
Timber Plants
.......................... 252
4.7
Unexpected Interactions with Wild Type
and Genetically Modified Populus Plants
........... 253
4.8
Nonmycorrhizal Plants
..................... 255
XIV Contents
4.9
Arabidopsis thaliana
...................... 256
4.10
Root
Organ
Culture.......................
259
5
Cell Wall Degrading Enzymes
................. 260
6
Conclusions
........................... 263
References and Selected Reading
..................... 264
16
Cellular Basidiomycete-Fungus Interactions
........ 267
Robert Bauer and Franz Oberwinkler
1
Introduction
........................... 267
2
Occurrence of Mycoparasites Within the Basidiomycota
. . 267
3
Hosts
............................... 268
4
Cellular Interactions
...................... 268
4.1
Colacosome-Interactions
.................... 268
4.2
Fusion-Interaction
....................... 275
5
Basidiomycetous Mycoparasitism, a Result of Convergent
Evolution?
............................ 277
6
Conclusions
........................... 278
References and Selected Reading
..................... 278
Section
D
17
Fungal Endophytes
....................... 281
Sita R.
Ghimire and Kevin D. Hyde
1
Introduction
........................... 281
2
Definition of a Fungal Endophyte
............... 281
3
Role of Endophytes
....................... 282
4
Modes of Endophytic Infection and Colonization
...... 283
5
Isolation of Endophytes
.................... 284
6
Molecular Characterization of Endophytes
.......... 285
7
Are Endophytes Responsible for Host Exclusivity/
Recurrence in Saprobic Fungi?
................. 286
8
Conclusions
........................... 287
References and Selected Reading
..................... 288
Contents
XV
18 Mycorrhizal Development
and Cytoskeleton
......... 293
Marjatta
Raudaskoski, Mika Tarkka and Sara Niini
1
Introduction
........................... 293
2 Cytoskeletal
Components
................... 293
2.1 Expression
of
Tubulin-Encoding Genes............ 294
2.2 Expression
of
Actin-Encoding Genes ............. 297
3
Organization of
Cytoskeleton in Endomycorrhiza...... 298
3.1
Root Cells ............................
298
3.2
Fungal Hyphae
......................... 300
4
Organization of Cytoskeleton in Ectomycorrhiza
...... 300
4.1
Root Cells
............................ 300
4.2
Fungal Hyphae
......................... 304
5
Regulation of Actin Cytoskeleton Organization
in Fungal Hyphae and Plant Cells
............... 305
6
Actin Binding-Proteins
..................... 307
7
Microtubule-Associated Proteins
............... 308
7.1
Plant Cells
............................ 308
7.2
Fungal Hyphae
......................... 310
8
Cell Cycle and Cytoskeleton in Mycorrhiza
.......... 313
9
Cytoskeletal Research Methods
................ 315
9.1
Indirect Immunofluorescence Microscopy
.......... 316
9.2
Microinjection
Method
..................... 317
9.3
Green Fluorescence Protein Technique
............ 317
References and Selected Reading
..................... 318
19
Functional Diversity of
Arbuscular
Mycorrhizal Fungi
on Root Surfaces
........................ 331
M. Zakaria Solaiman and Lynette K. Abbott
1
Introduction
........................... 331
2
Mycorrhiza Formation and Ecological Specificity
...... 332
2.1
Establishment of the Symbiosis
................ 333
2.2
Spore Germination and Hyphal Growth
........... 333
2.3
Role of Plant Root Exudates
.................. 333
3
Functioning of
Arbuscular
Mycorrhizas
in Nutrient Exchange
...................... 334
3.1
Metabolic Activity During Mycorrhiza Formation
...... 335
3.2
Gene Expression During Mycorrhiza Formation
....... 336
3.3
Nutrient Exchange Mechanisms in
Arbuscular
Mycorrhizas
336
4
Functional Diversity of
Arbuscular
Mycorrhizal Fungi
in Root and Hyphal Interactions
................ 338
XVI Contents
4.1
Diversity of
Arbuscular
Mycorrhizal Fungi Inside Roots
. . 339
4.2
Relationship Between Hyphae in the Root and in the Soil
. . 340
5
Role of
Arbuscular
Mycorrhizal Fungi Associated
with Roots in Soil Aggregation
................. 340
6
Environmental Influence on Functional Diversity
of
Arbuscular
Mycorrhizal Fungi
............... 341
7
Role of Plant Mutants in Studying the Interactions
Between
Arbuscular
Mycorrhizal Fungi and Roots
..... 341
8
Conclusion and Future Research Needs
............ 343
References and Selected Reading
..................... 343
20
Mycorrhizal Fungi and Plant Growth
Promoting Rhizobacteria
................... 351
José-Miguel
Barba, Rosario Azcón
and Concepción Azcón-Aguilar
1
Introduction
........................... 351
2
Main Types of Rhizosphere Microorganisms
......... 352
3
Mycorrhizal Fungi
........................ 353
4
Plant Growth Promoting Rhizobacteria
............ 354
5
Reasons for Studying
Arbuscular
Mycorrhizal Fungi
and Plant Growth Promoting Rhizobacteria Interactions
and Main Scenarios
....................... 356
6
Effect of Plant Growth Promoting Rhizobacteria
on Mycorrhiza Formation
................... 357
7
Effect of Mycorrhizas on the Establishment of Plant
Growth Promoting Rhizobacteria in the Rhizosphere
.... 357
8
Interactions Involved in Nutrient Cycling and Plant
Growth Promotion
....................... 359
9
Interactions for the Biological Control of Root Pathogens
. . 361
References and Selected Reading
..................... 362
21
Carbohydrates and Nitrogen: Nutrients
and Signals in Ectomycorrhizas
................ 373
Uwe Nehls
1
Introduction
........................... 373
2
Trehalose Utilization by Ectomycorrhizal Fungi
....... 374
3
Carbohydrate Uptake
...................... 374
4
Carbohydrate Metabolism
................... 376
5
Carbohydrate Storage
...................... 376
Contents XVII
6
Carbohydrates as Signal, Regulating Fungal
Gene Expression in Ectomycorrhizas
............. 377
7
Nitrogen
............................. 380
8
Utilization of Inorganic Nitrogen
............... 381
9
Utilization of Organic Nitrogen
................ 382
10
Proteolytic Activities of Ectomycorrhizal Fungi
....... 383
11
Uptake of
Amino
Acids
..................... 383
12
Regulation of Fungal Nitrogen Export in Mycorrhizas
by the Nitrogen-Status of Hyphae
............... 385
13
Carbohydrate and Nitrogen-Dependent Regulation
of Fungal Gene Expression
................... 385
14
Conclusions
........................... 385
References and Selected Reading
..................... 386
22
Nitrogen Transport and Metabolism
in Mycorrhizal Fungi and Mycorrhizas
............ 393
Arnaud Javelle, Michel Chalot, Annick Brun
and Bernard
Botton
1
Introduction
........................... 393
1.1
Ecological Significance of Ectomycorrhizas
......... 393
1.2
Nitrogen Uptake and
Translocation
by Ectomycorrhizas
. . 394
2
Nitrate and Nitrite Transport
.................. 395
2.1
Uptake Kinetics
......................... 395
2.2
Characterization of Nitrate and Nitrite Transporters
.... 395
3
Ammonium Transport
..................... 398
3.1
Physico-Chemical Properties of Ammonium:
Active Uptake Versus Diffusion
................ 398
3.2
Physiology of Ammonium Transport in Ectomycorrhizas
. . 399
3.3
Isolation of Ammonium Transporter Genes
......... 400
3.4
Regulation of the Ammonium Transporters
......... 400
3.5
Other Putative Functions of Ammonium Transporters
. . . 402
4
Amino
Acid Transport
..................... 403
4.1
Utilization of
Amino
Acids by Ectomycorrhizal Partners
. . 403
4.2
Molecular Regulation of
Amino
Acid Transport
....... 404
5
Reduction of Nitrate to Nitrite and Ammonium
....... 405
5.1
Reduction of Nitrate to Nitrite
................. 405
5.2
Reduction of Nitrite to Ammonium
.............. 406
5.3
Molecular Characterization of Nitrate Reductase
and Nitrite
Reducíase
...................... 406
6
Assimilation of Ammonium
.................. 409
6.1
Role and Properties of
Glutamate
Dehydrogenase
...... 410
XVIII
Contents
6.2
Role
and Properties
of
Glutaminę
Synthetase ........ 413
6.3
Role and Properties of
Glutamate
Synthase
.......... 415
7
Amino
Acid Metabolism
.................... 417
7.1
Utilization of Proteins by Ectomycorrhizal Fungi
and Ectomycorrhizas
...................... 417
7.2
Amino
Acids Used as Nitrogen and Carbon Sources
..... 418
8
Conclusion and Future Prospects
............... 419
References and Selected Reading
..................... 421
Section
E
23
Visualisation of Rhizosphere Interactions
of Pseudomonas and
ВасШкѕ
Biocontrol Strains
...... 431
Thomas F.C. Chin-A-
Wo eng,
Anastasia
L.
Lagopodi,
Ine H.M.
Mulders,
Guido
V.
Bloemberg
and Ben J.J. Lugtenberg
1
Introduction
........................... 431
2
Tomato Foot and Root Rot and the Need
for Biological Control
...................... 431
3
Selection of Antagonistic Strains
............... 432
3.1
Selection of Antagonistic Pseudomonas and Bacillus
sç.
. . . 432
3.2
In Vitro Antifungal Activity Test
................ 434
4
In Vivo Biocontrol Assays
.................... 434
4.1
Fusarium oxysporum
—
Tomato Biocontrol Assay
in a Potting Soil System
..................... 434
4.2
Gnotobiotic Fusarium oxysporum-Pythium ultimum
and Rhizoctonia solani-Tomato Bioassays
.......... 435
5
Microscope Analysis of Infection and Biocontrol
...... 435
5.1
Marking Fungi with
Autofluorescent
Proteins
........ 437
5.2
Marking Rhizosphere Bacteria with
Autofluorescent
Proteins
............................. 438
5.3
Confocal Laser Scanning Microscopy
of Rhizosphere Interactions
.................. 442
6
Conclusions
........................... 443
References and Selected Reading
..................... 443
Contents XIX
24 Microbial Community
Analysis in the Rhizosphere
by
in Situ and ex Situ Application
of Molecular Probing,
Biomarker
and Cultivation Techniques
............ 449
Anton
Hartmann, Rüdiger
Pukall,
Michael Rothballes, Stephan Gantner,
SiGRUN
Metz, Michael Schloter and Bernhard Mogge
1
Introduction
........................... 449
2 In Situ
Studies of
Microbial
Communities Using
Specific Fluorescence Labeling and Confocal
Laser Scanning Microscopy
.................. 451
2.1
Fluorescence in Situ Hybridization
.............. 451
2.2
Immunofluorescence Labeling Combined with
Fluorescence in Situ Hybridization
.............. 453
2.3
Application of Fluorescence Tagging and Reporter
Constructs
............................ 456
3
Ex Situ Studies of Microbial Communities
After Separation of Rhizosphere Compartments
....... 457
3.1
Recovery of Bacteria from Bulk Soil, Ecto- and
Endorhizosphere
........................ 457
3.2
Community Analysis by Cultivation and Dot Blot Studies
. . 458
3.3
Community Analysis by Fluorescence
in Situ Hybridization on Polycarbonate Filters
........ 460
3.4
Community Analysis by (RT) PCR- Amplification
of Phylogenetic Marker Genes, D/TGGE-Fingerprinting
and Clone Bank Studies
..................... 461
3.5
Community Analysis by Fatty Acid Pattern
and Community Level Physiological Profile Studies
..... 463
4
Conclusions
........................... 463
References and Selected Reading
..................... 464
25
Methods for Analysing the Interactions Between Epiphyllic
Microorganisms and Leaf Cuticles
.............. 471
Daniel Knoll and
Lukas Schreiber
1
Introduction
........................... 471
2
Physical Characterisation of Cuticle Surfaces
by Contact Angle Measurements
................ 471
3
Chemical Characterisation of Cuticle Surfaces
........ 473
4
A New in Vitro System for the Study
of Interactions Between Microbes and Cuticles
....... 475
XX
Contents
4.1
Isolated Cuticles as Model Surfaces for
Phyllosphere
Studies
475
4.2
Enzymatic Isolation of Plant Cuticles
............. 476
4.3
The Experimental Set-Up of the System
............ 476
4.4
Inoculation of Cuticular Membranes
with Epiphytic Microorganisms
................ 477
4.5
Measurement of Changes in Cuticular Transport Properties
479
4.6
Measuring Penetration of Microorganisms
Through Cuticular Membranes
................ 481
4.7
Determination of the Viable Cell Number
on the Cuticle Surface
...................... 483
4.8
Microscopic Visualisation of Microorganisms on the Cuticle
483
5
Conclusions
........................... 486
References and Selected Reading
..................... 486
26
Quantifying the Impact of ACC Deaminase-Containing
Bacteria on Plants
........................ 489
Donna M. Penrose and Bernard R. Glick
1
Introduction
........................... 489
2
Selection of Bacterial Strains that Contain ACC Deaminase
. 489
3
Culture Conditions for the Induction
of Bacterial ACC Deaminase Activity
............. 491
4
Gnotobiotic Root Elongation Assay
.............. 492
5
Measurement of ACC Deaminase Activity
.......... 493
5.1
Assay of ACC Deaminase Activity in Bacterial Extracts
. . . 494
6
Measurement of ACC in Plant Roots, Seed Tissues
and Seed Exudates
....................... 495
6.1
Collection of Canola Seed Tissue and
Exúdate
During Germination
...................... 495
6.2
Preparation of Plant Extracts
................. 496
6.3
Protein Concentration Assay
.................. 497
6.4
Measurement of ACC by HPLC
................. 498
References and Selected Reading
..................... 501
Contents XXI
27
Applications of Quantitative Microscopy in Studies
of Plant Surface Microbiology
................. 503
Frank B. Dazzo
1
Introduction
........................... 503
2
Quantitation of Symbiotic Interactions Between
Rhizobium and Legumes by Visual Counting Techniques
. . 504
2.1
The Modified
Fåhraeus
Slide Culture Technique
for Studies of the Root
—
Nodule Symbiosis
.......... 504
2.2
Attachment of Rhizobia to Legume Root Hairs
........ 506
2.3
Rhizobium-lnduced Root Hair Deformations
........ 508
2.4
Primary Entry of Rhizobia into Legume Roots
........ 509
2.5
In Situ Molecular Interactions Between Legumes
Roots and Surface-Colonizing Rhizobia
............ 511
2.6
Cross-Reactive Surface Antigens and Trifoliin A Host Lectin
511
2.7
Rhizobium Acidic Heteropolysaccharides
........... 513
2.8
Rhizobium Lipopolysaccharides
................ 516
2.9
Chitolipooligosaccharide Nod Factors
............ 518
2.10
Epidermal Pit Erosions
..................... 522
2.11
Elidtation of Root Hair Wall Peroxidase by Rhizobia
.... 524
2.12
In Situ Gene Expression
.................... 525
3
Quantitation of Symbiotic Interactions Between
Rhizobium and Legumes by Image Analysis
......... 526
3.1
Definitive Elucidation of the Nature of Rhizobium
Extracellular Microfibrils
.................... 526
3.2
Rhizobial Modulation of Root Hair Cytoplasmic Streaming
527
3.3
Motility of Rhizobia in the External Root Environment
. . . 527
3.4
Root Hair Alterations Affecting Their Dynamic
Growth Extension and Primary Host Infection
........ 528
4
A Working Model for Very Early Stages of Root
Hair Infection by Rhizobia
................... 529
5
Improvements in Specimen Preparation and
Imaging Optics for Plant Rhizoplane Microbiology
..... 529
6
CMEIAS: A New Generation of Image Analysis
Software for in Situ Studies of Microbial Ecology
...... 531
6.1
CMEIAS v.
1.27:
Major Advancements in Bacterial
Morphotype
Classification
................... 531
6.2
CMEIAS v.
3.0:
Comprehensive Image Analysis
of Microbial Communities
................... 532
6.3
CMEIAS v.
3.0:
Plotless and Plot-Based Spatial
Distribution Analysis of Root Colonization
.......... 533
6.4
CMEIAS v.
3.0:
In Situ Analysis of Microbial
Communities on Plant Phylloplanes
.............. 535
XXII Contents
6.5
CMEIAS
v.
3.0: In Situ Geostatistical
Analysis
of Root Colonization by Pioneer Rhizobacteria
....... 540
6.6
CMEIAS v.
3.0:
Quantitative Autecological Biogeography
of the Rhizobium-Blce Association
.............. 541
6.7
CMEIAS v.
3.0:
Spatial Scale Analysis of in Situ
Quorum Sensing by Root-Colonizing Bacteria
........ 543
7
Conclusions
........................... 544
References and Selected Reading
..................... 544
28
Analysis of Microbial Population Genetics
.......... 551
Emanuele
G.
Biondi, Alessio Mengoni
and Marco Bazzicalupo
1
Introduction
........................... 551
2
Materials
for RAPD,AFLP and ITS
.............. 552
3
RAPD
............................... 553
4
AFLP
............................... 556
5
ITS-RFLP
Analysis
....................... 559
6
Statistical analysis........................
561
7
Concluding Remarks
...................... 563
References and Selected Reading
..................... 564
29
Functional Genomic Approaches for Studies
of Mycorrhizal Symbiosis
................... 567
Gopi K. Podila and
Luisa Lanfranco
1
Introduction
........................... 567
2
Material and Methods
...................... 568
2.1
Equipment
............................ 568
2.2
Biological Material
....................... 569
2.3
RNA
Extraction
......................... 569
3
RNA
Quantification
....................... 570
3.1
Construction of a cDNA Library
................ 570
4
Conversion Protocol
...................... 577
4.1
Evaluation of the Quality of the cDNA Library
........ 577
5
Troubleshooting
......................... 578
6
Sequencing Strategies
...................... 578
6.1
Data Analysis
.......................... 579
6.2
Sequence Homology Comparisons
.............. 579
Contents XXIII
6.3
Examples of Expressed Sequence Tag Data Analysis
..... 579
7
Macroarrays
........................... 582
7.1
PCR Amplification of cDNA Inserts
.............. 582
7.2
Purification and Quantification of PCR Products
...... 583
7.3
Printing of Macroarrays
.................... 583
7.4
Generation of Exponential cDNA Probes from
RNA
for Macroarrays and Hybridization Analysis
...... 584
7.5
Exponential Amplification of the sscDNAs
.......... 585
8
Generation of
Radiolabeled
Probes
.............. 585
9
Hybridization of Macroarrays to
Radiolabeled
Probes
. . . 586
10
Data Analysis
.......................... 586
10.1
Data Analysis Autoradiography Images on X-ray Films
. . . 587
11
Example of
Laccarla
bicolor
Macroarrays
........... 588
12
Conclusions
........................... 590
References and Selected Reading
..................... 591
30
Axenic Culture of Symbiotic Fungus Piriformospora
indica
593
Giang Huong Pham,
Rina Kumari,
Anjana Singh,
Rajani
Malla,
Ram
Prasad, Minu
Sachdev,
Michael Kaldorf, Francois Buscot,
Ralf Oelmuller,
Rüdiger Hampp,
Anil Kumar Saxena,
Karl-Heinz
Rexer,
Gerhard Kost
and Ajit
Varma
1
Introduction
........................... 593
2
Morphology
........................... 593
3
Taxonomy of the Fungus
.................... 595
4
Chlamydospore Formation and Germination
........ 597
5
Cultivation
............................ 597
6
Carbon and Energy Sources
.................. 600
7
Biomass on Individual
Amino
Acids
.............. 604
8
Growth on Complex Media
................... 604
9
Phosphatic Nutrients
...................... 605
10
Composition of Media
..................... 606
11
Conclusions
........................... 612
References and Selected Reading
..................... 612
Subject Index
................................ 615
|
| adam_txt |
Contents
The State
of the Art
.
AjiT
Varma, Lynette K.
Abbott, Dietrich Werner
and
Rüdiger Hampp
Section A
2
Root Colonisation Following Seed Inoculation
. 13
Thomas EC. Chin-A-Woeng and Ben J.J. Lugtenberg
1
Introduction
. 13
2
Bacterial Root Colonisation
. 13
3
Analysis of Tomato Root Tip Colonisation
After Seed Inoculation Using a Gnotobiotic Assay
. 14
3.1
Description of the Gnotobiotic System
. 14
3.2
Seed Disinfection
. 15
3.3
Growth and Preparation of Bacteria
. 16
3.4
Seed Inoculation
. 17
3.5
Analysis of the Tomato Root Tip
. 17
3.6
Confocal Laser Scanning Microscopy
. 18
4
Genetic Tools for Studying Root Colonisation
. 18
4.1
Marking and Selecting Bacteria
. 18
4.2
Rhizosphere-Stable Plasmids
. 21
4.3
Genetic and Metabolic Burdens
. 21
5
Behaviour of Root-Colonising
Pseudomonas Bacteria in a Gnotobiotic System
. 22
5.1
Colonisation Strategies of Bacteria
. 22
5.2
Competitive Colonisation Studies
. 23
5.3
Monocots versus Dicots
. 25
6
Influence of Abiotic and Biotic Factors
. 25
VIII Contents
6.1
Abiotic
Factors
. 25
6.2
Biotic Factors
. 27
7
Conclusions
. 28
References and Selected Reading
. 28
3
Methanogenic Microbial Communities Associated
with Aquatic Plants
. 35
Ralf Conrad
1
Introduction
. 35
2
Role of Plants in Emission of CH4 to the Atmosphere
. 35
3
Role of Photosynthates and Plant Debris for CH4 Production
38
4
Methanogenic Microbial Communities on Plant Debris
. 40
5
Methanogenic Microbial Communities on Roots
. 42
6
Interaction of
Methanogens
and Methanotrophs
. 44
References and Selected Reading
. 45
4
Role of Functional Groups of Microorganisms
on the Rhizosphere Microcosm Dynamics
. 51
Galdino
Andrade
1
Introduction
. 51
2
General Aspects of Functional Groups
of Soil Microorganisms
. 52
3
Carbon Cycle Functional Groups
. 53
4
Functional Groups of Microorganisms of the Nitrogen Cycle
55
5
Functional Groups of Microorganisms of the Sulphur Cycle
57
6
Functional Groups of Microorganisms
of the Phosphorus Cycle
. 59
7
Dynamics of the Rhizosphere Functional Groups
of Microorganisms
. 60
8
Relationship Among
r
and
к
Strategist Functional Groups
. 61
9
Arbuscular Mycorrhizal
Fungi Dynamics
in the Rhizosphere
. 61
10
Dynamics Among the Functional Micro-Organism Groups
of the Carbon, Nitrogen, Phosphorus and Sulphur Cycles
. . 65
References and Selected Reading
. 68
Contents
IX
5
Diversity and Functions of Soil
Microflora
in Development of Plants
. 71
Ramesh CHandER Kuhad, David Manohar Kothamasi,
K.K. Tripathi and Ajay Singh
1
Introduction
. 71
2
Functional Diversity of Soil
Microflora
. 72
3
Role of Soil
Microflora in
Plant Development
. 76
3.1
Mycorrhiza
. 76
3.2
Actinorhiza
. 80
3.3
Plant Growth-Promoting Rhizobacteria
. 82
3.4
Phosphate-Solubilizing Microorganisms
. 84
3.5
Lignocellulolytic Microorganisms
. 85
4
Plant Growth Promoting Substances Produced
by Soil Microbes
. 88
5
Conclusions
. 90
References and Selected Reading
. 91
6
Signalling in the Rhizobia-Legumes Symbiosis
. 99
Dietrich Werner
1
Introduction
. 99
2
The Signals from the Host Plants
. 101
2.1
Phenylpropanoids: Simple Phenolics, Flavonoids
and Isoflavonoids
. 102
2.2
Metabolization of Flavonoids and Isoflavonoids
. 104
2.3
Vitamins as Growth Factors and Signal Molecules
. 106
3
Signals from the Microsymbionts
. 107
3.1
Nod Factors
. 107
3.2
Cyclic Glucans
. 109
3.3
Lipopolysaccharides
. 110
3.4
Exopolysaccharides
. 110
4
Signal Perception and Molecular Biology
of Nodule Initiation
.
Ill
References and Selected Reading
. 114
X
Contents
Section
В
7
The Functional Groups of Micro-organisms Used
as Bio-indicator on Soil Disturbance Caused
by Biotech Products such as Bacillus thuringiensis
and Bt Transgenic Plants
. 121
Galdino
Andrade
1
Introduction
. 121
2
General Aspects of Bacillus thuringiensis
. 122
3
Survival in the Soil
. 123
4
History of Bacillus thuringiensis-Tramgmic Plants
. 124
5
Persistence of the Protein Crystal in the Soil
. 125
6
Effect of Bacillus thuringiensis and Its Bio-insecticide
Protein on Functional Soil Microorganism Assemblage
. . . 126
References and Selected Reading
. 130
8
The Use of ACC Deaminase-Containing
Plant Growth-Promoting Bacteria to Protect Plants
Against the Deleterious Effects of
Ethylene
. 133
Bernard R. Glick and Donna M. Penrose
1
Introduction
. 133
2
Ethylene
. 134
3
ACCDeaminase
. 135
3.1
Treatment of Plants with ACC Deaminase
Containing Bacteria
. 137
4
Conclusions
. 140
References and Selected Reading
. 141
9
Interactions Between Epiphyllic Microorganisms
and Leaf Cuticles
. 145
Lukas Schreiber,
Ursula Krimm and Daniel Knoll
1
Introduction
. 145
2
Physical and Chemical Parameters of the Phyllosphere
. 147
3
Leaf Surface Colonisation and Species Composition
. 149
4
Alteration of Leaf Surface Wetting
. 150
5
Interaction of Bacteria with Isolated Plant Cuticles
. 152
6
Conclusions
. 153
References and Selected Reading
. 154
Contents
XI
10
Developmental Interactions Between Clavidpitaleans
and Their Host Plants
. 157
James
E
White Jr., Faith
Belanger, Raymond
Sullivan,
Elizabeth Lewis,
Melinda
Μου,
William Meyer
and Charles W. Bacon
1
Introduction
. 157
2
Endophyte/Epibiont Niche
. 157
3
Coevolution of Clavicipitalean Fungi with Grass Hosts
. . . 158
4
The Jump from Insects to Plants
. 158
4.1
Trans-Kingdom Jump
. 158
4.2
Intermediate Stages in the Transition to Plants
. 158
4.3
Parasitism of Grass Meristematic Tissues
. 160
5
Developmental Differentiation of Endophytic
and Epiphyllous Mycelium
. 160
5.1
Plant Cell Wall Alteration
. 160
5.2
Endophytic Mycelial Growth
. 160
5.3
Control of Endophytic Mycelial Development
. 163
5.4
Epiphyllous Mycelial Development
. 163
5.5
Expression of Fungal Secreted Hydrolytic
Enzymes in Infected Plants
. 164
6
Modifications of Plant Tissues for Nutrient Acquisition
. . . 165
6.1
Development of the
Stroma
in
Epichloë
. 165
6.2
Stroma
Development in Myriogenospora
. 166
6.3
Mechanisms for Modifying Plant Tissues
. 168
6.4
Evaporative-Flow Mechanism for Nutrient Acquisition
. . . 169
6.5
The Cytokinin Induction Hypothesis
. 169
7
Evolution of Asexual Derivatives of
Epichloë
. 171
7.1
Reproduction and Loss of Sexual Reproduction
. 171
7.2
The Hypotheses
. 172
7.3
The Process of
Stroma
Development and its Loss
. 173
7.4
The Shift from Pathogen to Mutualist
. 174
8
Conclusions
. 174
References and Selected Reading
. 174
11
Interactions of Microbes with Genetically Modified Plants
. 179
Michael Kaldorp, Chi Zhang,
Uwe Nehls,
Rüdiger Hampp
and
François Buscot
1
Introduction
. 179
2
Changes in Microbial Communities Induced
by Genetically Modified Plants
. 181
XII Contents
3
Impact of Genetically Modified Plants
on Symbiotic Interactions
. 184
4
Horizontal Gene Transfer
. 186
5
Conclusions
. 191
References and Selected Reading
. 192
Section
С
12
Interaction Between Soil Bacteria
and Ectomycorrhiza-Forming Fungi
. 197
Rüdiger Hampp
and AndREAS Maier
1
Introduction
. 197
2
Bacteria
. 198
3
Bacterial Community Structure
. 198
4
Association of Bacteria with Fungal/Ectomycorrhizal
Structures
. 199
5
Bacteria Associated with Sporocarps and Ectomycorrhiza
. 200
6
Benefits from Bacteria/Ectomycorrhiza Interactions
. 201
7
Possible Mechanisms of Interaction
. 202
8
Biochemical Evidence for Interaction
. 203
9
Impacts of Environmental Pollution
. 206
10
Conclusions
. 206
References and Selected Reading
. 207
13
The Surface of Ectomycorrhizal Roots and the
Interaction with Ectomycorrhizal Fungi
. 211
Ingrid Kottke
1
Introduction
. 211
2
Long and Short Roots of Ectomycorrhiza-Forming Plants
. 212
3
A Cuticle-Like Layer on the Surface of Short Roots
. 214
4
Involvement of the Cuticle-Like Layer
in Mycorrhiza Formation
. 218
5
Involvement of the Cuticle-Like Layer in Hyphal Attachment
218
6
Digestion of the Suberin Layer and the Cell Wall
of the Root Cap
. 220
7
Hartig
Net Formation
. 221
8
Pectins in the Cortical Cell Walls of Nonmycorrhizal
Long and Mycorrhizal Short Roots
. 222
9
Conclusions
. 223
References and Selected Reading
. 224
Contents XIII
14
Cellular Ustilaginomycete
—
Plant Interactions
. 227
Robert Bauer and Franz Oberwinkler
1
Introduction
. 227
2
The Term Smut Fungus
. 227
3
Life Cycle
. 228
4
Hosts
. 228
5
Cellular Interactions
. 229
5.1
Local Interaction Zones
. 230
5.2
Enlarged Interaction Zones
. 234
6
Conclusions
. 235
References and Selected Reading
. 236
15
Interaction of Piriformospora
indica
with Diverse Microorganisms and Plants
. 237
Giang Huong Pham, Anjana Singh, Rajani
Malla,
Rina Kumari,
,
Ram
Prasad, Minu
Sachdev,
Karl-Heinz Rexer, Gerhard Kost, Patricia
Luis,
Michael Kaldorf,
François Buscot, Sylvie
Herrmann,
Tanja Peskan, Ralf Oelmüller,
Anil Kumar Saxena,
Stephane Declerck, Maria Mittag, Edith Stabentheiner,
Solveig
Hehl
and Ajit
Varma
1
Introduction
. 237
2
Interaction with Microorganisms
. 238
2.1
Rhizobacteria
. 238
2.2
Chlamydomonas reinhardtii
. 239
2.3
Sebacina vermifera
. 239
2.4
Other Soil Fungi
. 240
2.5
Gaeumannomyces graminis
. 240
3
Interaction with Bryophyte
. 242
4
Interaction with Higher Plants
. 242
4.1
Monocots
. 245
4.2
Legumes
. 245
4.3
Orchids
. 246
4.4
Medicinal Plants
. 247
4.5
Economically Important Plants
. 249
4.6
Timber Plants
. 252
4.7
Unexpected Interactions with Wild Type
and Genetically Modified Populus Plants
. 253
4.8
Nonmycorrhizal Plants
. 255
XIV Contents
4.9
Arabidopsis thaliana
. 256
4.10
Root
Organ
Culture.
259
5
Cell Wall Degrading Enzymes
. 260
6
Conclusions
. 263
References and Selected Reading
. 264
16
Cellular Basidiomycete-Fungus Interactions
. 267
Robert Bauer and Franz Oberwinkler
1
Introduction
. 267
2
Occurrence of Mycoparasites Within the Basidiomycota
. . 267
3
Hosts
. 268
4
Cellular Interactions
. 268
4.1
Colacosome-Interactions
. 268
4.2
Fusion-Interaction
. 275
5
Basidiomycetous Mycoparasitism, a Result of Convergent
Evolution?
. 277
6
Conclusions
. 278
References and Selected Reading
. 278
Section
D
17
Fungal Endophytes
. 281
Sita R.
Ghimire and Kevin D. Hyde
1
Introduction
. 281
2
Definition of a Fungal Endophyte
. 281
3
Role of Endophytes
. 282
4
Modes of Endophytic Infection and Colonization
. 283
5
Isolation of Endophytes
. 284
6
Molecular Characterization of Endophytes
. 285
7
Are Endophytes Responsible for Host Exclusivity/
Recurrence in Saprobic Fungi?
. 286
8
Conclusions
. 287
References and Selected Reading
. 288
Contents
XV
18 Mycorrhizal Development
and Cytoskeleton
. 293
Marjatta
Raudaskoski, Mika Tarkka and Sara Niini
1
Introduction
. 293
2 Cytoskeletal
Components
. 293
2.1 Expression
of
Tubulin-Encoding Genes. 294
2.2 Expression
of
Actin-Encoding Genes . 297
3
Organization of
Cytoskeleton in Endomycorrhiza. 298
3.1
Root Cells .
298
3.2
Fungal Hyphae
. 300
4
Organization of Cytoskeleton in Ectomycorrhiza
. 300
4.1
Root Cells
. 300
4.2
Fungal Hyphae
. 304
5
Regulation of Actin Cytoskeleton Organization
in Fungal Hyphae and Plant Cells
. 305
6
Actin Binding-Proteins
. 307
7
Microtubule-Associated Proteins
. 308
7.1
Plant Cells
. 308
7.2
Fungal Hyphae
. 310
8
Cell Cycle and Cytoskeleton in Mycorrhiza
. 313
9
Cytoskeletal Research Methods
. 315
9.1
Indirect Immunofluorescence Microscopy
. 316
9.2
Microinjection
Method
. 317
9.3
Green Fluorescence Protein Technique
. 317
References and Selected Reading
. 318
19
Functional Diversity of
Arbuscular
Mycorrhizal Fungi
on Root Surfaces
. 331
M. Zakaria Solaiman and Lynette K. Abbott
1
Introduction
. 331
2
Mycorrhiza Formation and Ecological Specificity
. 332
2.1
Establishment of the Symbiosis
. 333
2.2
Spore Germination and Hyphal Growth
. 333
2.3
Role of Plant Root Exudates
. 333
3
Functioning of
Arbuscular
Mycorrhizas
in Nutrient Exchange
. 334
3.1
Metabolic Activity During Mycorrhiza Formation
. 335
3.2
Gene Expression During Mycorrhiza Formation
. 336
3.3
Nutrient Exchange Mechanisms in
Arbuscular
Mycorrhizas
336
4
Functional Diversity of
Arbuscular
Mycorrhizal Fungi
in Root and Hyphal Interactions
. 338
XVI Contents
4.1
Diversity of
Arbuscular
Mycorrhizal Fungi Inside Roots
. . 339
4.2
Relationship Between Hyphae in the Root and in the Soil
. . 340
5
Role of
Arbuscular
Mycorrhizal Fungi Associated
with Roots in Soil Aggregation
. 340
6
Environmental Influence on Functional Diversity
of
Arbuscular
Mycorrhizal Fungi
. 341
7
Role of Plant Mutants in Studying the Interactions
Between
Arbuscular
Mycorrhizal Fungi and Roots
. 341
8
Conclusion and Future Research Needs
. 343
References and Selected Reading
. 343
20
Mycorrhizal Fungi and Plant Growth
Promoting Rhizobacteria
. 351
José-Miguel
Barba, Rosario Azcón
and Concepción Azcón-Aguilar
1
Introduction
. 351
2
Main Types of Rhizosphere Microorganisms
. 352
3
Mycorrhizal Fungi
. 353
4
Plant Growth Promoting Rhizobacteria
. 354
5
Reasons for Studying
Arbuscular
Mycorrhizal Fungi
and Plant Growth Promoting Rhizobacteria Interactions
and Main Scenarios
. 356
6
Effect of Plant Growth Promoting Rhizobacteria
on Mycorrhiza Formation
. 357
7
Effect of Mycorrhizas on the Establishment of Plant
Growth Promoting Rhizobacteria in the Rhizosphere
. 357
8
Interactions Involved in Nutrient Cycling and Plant
Growth Promotion
. 359
9
Interactions for the Biological Control of Root Pathogens
. . 361
References and Selected Reading
. 362
21
Carbohydrates and Nitrogen: Nutrients
and Signals in Ectomycorrhizas
. 373
Uwe Nehls
1
Introduction
. 373
2
Trehalose Utilization by Ectomycorrhizal Fungi
. 374
3
Carbohydrate Uptake
. 374
4
Carbohydrate Metabolism
. 376
5
Carbohydrate Storage
. 376
Contents XVII
6
Carbohydrates as Signal, Regulating Fungal
Gene Expression in Ectomycorrhizas
. 377
7
Nitrogen
. 380
8
Utilization of Inorganic Nitrogen
. 381
9
Utilization of Organic Nitrogen
. 382
10
Proteolytic Activities of Ectomycorrhizal Fungi
. 383
11
Uptake of
Amino
Acids
. 383
12
Regulation of Fungal Nitrogen Export in Mycorrhizas
by the Nitrogen-Status of Hyphae
. 385
13
Carbohydrate and Nitrogen-Dependent Regulation
of Fungal Gene Expression
. 385
14
Conclusions
. 385
References and Selected Reading
. 386
22
Nitrogen Transport and Metabolism
in Mycorrhizal Fungi and Mycorrhizas
. 393
Arnaud Javelle, Michel Chalot, Annick Brun
and Bernard
Botton
1
Introduction
. 393
1.1
Ecological Significance of Ectomycorrhizas
. 393
1.2
Nitrogen Uptake and
Translocation
by Ectomycorrhizas
. . 394
2
Nitrate and Nitrite Transport
. 395
2.1
Uptake Kinetics
. 395
2.2
Characterization of Nitrate and Nitrite Transporters
. 395
3
Ammonium Transport
. 398
3.1
Physico-Chemical Properties of Ammonium:
Active Uptake Versus Diffusion
. 398
3.2
Physiology of Ammonium Transport in Ectomycorrhizas
. . 399
3.3
Isolation of Ammonium Transporter Genes
. 400
3.4
Regulation of the Ammonium Transporters
. 400
3.5
Other Putative Functions of Ammonium Transporters
. . . 402
4
Amino
Acid Transport
. 403
4.1
Utilization of
Amino
Acids by Ectomycorrhizal Partners
. . 403
4.2
Molecular Regulation of
Amino
Acid Transport
. 404
5
Reduction of Nitrate to Nitrite and Ammonium
. 405
5.1
Reduction of Nitrate to Nitrite
. 405
5.2
Reduction of Nitrite to Ammonium
. 406
5.3
Molecular Characterization of Nitrate Reductase
and Nitrite
Reducíase
. 406
6
Assimilation of Ammonium
. 409
6.1
Role and Properties of
Glutamate
Dehydrogenase
. 410
XVIII
Contents
6.2
Role
and Properties
of
Glutaminę
Synthetase . 413
6.3
Role and Properties of
Glutamate
Synthase
. 415
7
Amino
Acid Metabolism
. 417
7.1
Utilization of Proteins by Ectomycorrhizal Fungi
and Ectomycorrhizas
. 417
7.2
Amino
Acids Used as Nitrogen and Carbon Sources
. 418
8
Conclusion and Future Prospects
. 419
References and Selected Reading
. 421
Section
E
23
Visualisation of Rhizosphere Interactions
of Pseudomonas and
ВасШкѕ
Biocontrol Strains
. 431
Thomas F.C. Chin-A-
Wo eng,
Anastasia
L.
Lagopodi,
Ine H.M.
Mulders,
Guido
V.
Bloemberg
and Ben J.J. Lugtenberg
1
Introduction
. 431
2
Tomato Foot and Root Rot and the Need
for Biological Control
. 431
3
Selection of Antagonistic Strains
. 432
3.1
Selection of Antagonistic Pseudomonas and Bacillus
sç.
. . . 432
3.2
In Vitro Antifungal Activity Test
. 434
4
In Vivo Biocontrol Assays
. 434
4.1
Fusarium oxysporum
—
Tomato Biocontrol Assay
in a Potting Soil System
. 434
4.2
Gnotobiotic Fusarium oxysporum-Pythium ultimum
and Rhizoctonia solani-Tomato Bioassays
. 435
5
Microscope Analysis of Infection and Biocontrol
. 435
5.1
Marking Fungi with
Autofluorescent
Proteins
. 437
5.2
Marking Rhizosphere Bacteria with
Autofluorescent
Proteins
. 438
5.3
Confocal Laser Scanning Microscopy
of Rhizosphere Interactions
. 442
6
Conclusions
. 443
References and Selected Reading
. 443
Contents XIX
24 Microbial Community
Analysis in the Rhizosphere
by
in Situ and ex Situ Application
of Molecular Probing,
Biomarker
and Cultivation Techniques
. 449
Anton
Hartmann, Rüdiger
Pukall,
Michael Rothballes, Stephan Gantner,
SiGRUN
Metz, Michael Schloter and Bernhard Mogge
1
Introduction
. 449
2 In Situ
Studies of
Microbial
Communities Using
Specific Fluorescence Labeling and Confocal
Laser Scanning Microscopy
. 451
2.1
Fluorescence in Situ Hybridization
. 451
2.2
Immunofluorescence Labeling Combined with
Fluorescence in Situ Hybridization
. 453
2.3
Application of Fluorescence Tagging and Reporter
Constructs
. 456
3
Ex Situ Studies of Microbial Communities
After Separation of Rhizosphere Compartments
. 457
3.1
Recovery of Bacteria from Bulk Soil, Ecto- and
Endorhizosphere
. 457
3.2
Community Analysis by Cultivation and Dot Blot Studies
. . 458
3.3
Community Analysis by Fluorescence
in Situ Hybridization on Polycarbonate Filters
. 460
3.4
Community Analysis by (RT) PCR- Amplification
of Phylogenetic Marker Genes, D/TGGE-Fingerprinting
and Clone Bank Studies
. 461
3.5
Community Analysis by Fatty Acid Pattern
and Community Level Physiological Profile Studies
. 463
4
Conclusions
. 463
References and Selected Reading
. 464
25
Methods for Analysing the Interactions Between Epiphyllic
Microorganisms and Leaf Cuticles
. 471
Daniel Knoll and
Lukas Schreiber
1
Introduction
. 471
2
Physical Characterisation of Cuticle Surfaces
by Contact Angle Measurements
. 471
3
Chemical Characterisation of Cuticle Surfaces
. 473
4
A New in Vitro System for the Study
of Interactions Between Microbes and Cuticles
. 475
XX
Contents
4.1
Isolated Cuticles as Model Surfaces for
Phyllosphere
Studies
475
4.2
Enzymatic Isolation of Plant Cuticles
. 476
4.3
The Experimental Set-Up of the System
. 476
4.4
Inoculation of Cuticular Membranes
with Epiphytic Microorganisms
. 477
4.5
Measurement of Changes in Cuticular Transport Properties
479
4.6
Measuring Penetration of Microorganisms
Through Cuticular Membranes
. 481
4.7
Determination of the Viable Cell Number
on the Cuticle Surface
. 483
4.8
Microscopic Visualisation of Microorganisms on the Cuticle
483
5
Conclusions
. 486
References and Selected Reading
. 486
26
Quantifying the Impact of ACC Deaminase-Containing
Bacteria on Plants
. 489
Donna M. Penrose and Bernard R. Glick
1
Introduction
. 489
2
Selection of Bacterial Strains that Contain ACC Deaminase
. 489
3
Culture Conditions for the Induction
of Bacterial ACC Deaminase Activity
. 491
4
Gnotobiotic Root Elongation Assay
. 492
5
Measurement of ACC Deaminase Activity
. 493
5.1
Assay of ACC Deaminase Activity in Bacterial Extracts
. . . 494
6
Measurement of ACC in Plant Roots, Seed Tissues
and Seed Exudates
. 495
6.1
Collection of Canola Seed Tissue and
Exúdate
During Germination
. 495
6.2
Preparation of Plant Extracts
. 496
6.3
Protein Concentration Assay
. 497
6.4
Measurement of ACC by HPLC
. 498
References and Selected Reading
. 501
Contents XXI
27
Applications of Quantitative Microscopy in Studies
of Plant Surface Microbiology
. 503
Frank B. Dazzo
1
Introduction
. 503
2
Quantitation of Symbiotic Interactions Between
Rhizobium and Legumes by Visual Counting Techniques
. . 504
2.1
The Modified
Fåhraeus
Slide Culture Technique
for Studies of the Root
—
Nodule Symbiosis
. 504
2.2
Attachment of Rhizobia to Legume Root Hairs
. 506
2.3
Rhizobium-lnduced Root Hair Deformations
. 508
2.4
Primary Entry of Rhizobia into Legume Roots
. 509
2.5
In Situ Molecular Interactions Between Legumes
Roots and Surface-Colonizing Rhizobia
. 511
2.6
Cross-Reactive Surface Antigens and Trifoliin A Host Lectin
511
2.7
Rhizobium Acidic Heteropolysaccharides
. 513
2.8
Rhizobium Lipopolysaccharides
. 516
2.9
Chitolipooligosaccharide Nod Factors
. 518
2.10
Epidermal Pit Erosions
. 522
2.11
Elidtation of Root Hair Wall Peroxidase by Rhizobia
. 524
2.12
In Situ Gene Expression
. 525
3
Quantitation of Symbiotic Interactions Between
Rhizobium and Legumes by Image Analysis
. 526
3.1
Definitive Elucidation of the Nature of Rhizobium
Extracellular Microfibrils
. 526
3.2
Rhizobial Modulation of Root Hair Cytoplasmic Streaming
527
3.3
Motility of Rhizobia in the External Root Environment
. . . 527
3.4
Root Hair Alterations Affecting Their Dynamic
Growth Extension and Primary Host Infection
. 528
4
A Working Model for Very Early Stages of Root
Hair Infection by Rhizobia
. 529
5
Improvements in Specimen Preparation and
Imaging Optics for Plant Rhizoplane Microbiology
. 529
6
CMEIAS: A New Generation of Image Analysis
Software for in Situ Studies of Microbial Ecology
. 531
6.1
CMEIAS v.
1.27:
Major Advancements in Bacterial
Morphotype
Classification
. 531
6.2
CMEIAS v.
3.0:
Comprehensive Image Analysis
of Microbial Communities
. 532
6.3
CMEIAS v.
3.0:
Plotless and Plot-Based Spatial
Distribution Analysis of Root Colonization
. 533
6.4
CMEIAS v.
3.0:
In Situ Analysis of Microbial
Communities on Plant Phylloplanes
. 535
XXII Contents
6.5
CMEIAS
v.
3.0: In Situ Geostatistical
Analysis
of Root Colonization by Pioneer Rhizobacteria
. 540
6.6
CMEIAS v.
3.0:
Quantitative Autecological Biogeography
of the Rhizobium-Blce Association
. 541
6.7
CMEIAS v.
3.0:
Spatial Scale Analysis of in Situ
Quorum Sensing by Root-Colonizing Bacteria
. 543
7
Conclusions
. 544
References and Selected Reading
. 544
28
Analysis of Microbial Population Genetics
. 551
Emanuele
G.
Biondi, Alessio Mengoni
and Marco Bazzicalupo
1
Introduction
. 551
2
Materials
for RAPD,AFLP and ITS
. 552
3
RAPD
. 553
4
AFLP
. 556
5
ITS-RFLP
Analysis
. 559
6
Statistical analysis.
561
7
Concluding Remarks
. 563
References and Selected Reading
. 564
29
Functional Genomic Approaches for Studies
of Mycorrhizal Symbiosis
. 567
Gopi K. Podila and
Luisa Lanfranco
1
Introduction
. 567
2
Material and Methods
. 568
2.1
Equipment
. 568
2.2
Biological Material
. 569
2.3
RNA
Extraction
. 569
3
RNA
Quantification
. 570
3.1
Construction of a cDNA Library
. 570
4
Conversion Protocol
. 577
4.1
Evaluation of the Quality of the cDNA Library
. 577
5
Troubleshooting
. 578
6
Sequencing Strategies
. 578
6.1
Data Analysis
. 579
6.2
Sequence Homology Comparisons
. 579
Contents XXIII
6.3
Examples of Expressed Sequence Tag Data Analysis
. 579
7
Macroarrays
. 582
7.1
PCR Amplification of cDNA Inserts
. 582
7.2
Purification and Quantification of PCR Products
. 583
7.3
Printing of Macroarrays
. 583
7.4
Generation of Exponential cDNA Probes from
RNA
for Macroarrays and Hybridization Analysis
. 584
7.5
Exponential Amplification of the sscDNAs
. 585
8
Generation of
Radiolabeled
Probes
. 585
9
Hybridization of Macroarrays to
Radiolabeled
Probes
. . . 586
10
Data Analysis
. 586
10.1
Data Analysis Autoradiography Images on X-ray Films
. . . 587
11
Example of
Laccarla
bicolor
Macroarrays
. 588
12
Conclusions
. 590
References and Selected Reading
. 591
30
Axenic Culture of Symbiotic Fungus Piriformospora
indica
593
Giang Huong Pham,
Rina Kumari,
Anjana Singh,
Rajani
Malla,
Ram
Prasad, Minu
Sachdev,
Michael Kaldorf, Francois Buscot,
Ralf Oelmuller,
Rüdiger Hampp,
Anil Kumar Saxena,
Karl-Heinz
Rexer,
Gerhard Kost
and Ajit
Varma
1
Introduction
. 593
2
Morphology
. 593
3
Taxonomy of the Fungus
. 595
4
Chlamydospore Formation and Germination
. 597
5
Cultivation
. 597
6
Carbon and Energy Sources
. 600
7
Biomass on Individual
Amino
Acids
. 604
8
Growth on Complex Media
. 604
9
Phosphatic Nutrients
. 605
10
Composition of Media
. 606
11
Conclusions
. 612
References and Selected Reading
. 612
Subject Index
. 615 |
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| illustrated | Illustrated |
| index_date | 2024-07-02T21:42:47Z |
| indexdate | 2024-07-09T21:20:04Z |
| institution | BVB |
| isbn | 9783540740506 |
| language | English |
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| spelling | Plant surface microbiology Ajit Varma ... (eds.) [Taschenbuch-Ausg.] Berlin [u.a.] Springer 2008 XXXI, 628 S. Ill., graph. Dars. txt rdacontent n rdamedia nc rdacarrier Plant surfaces Microbiology Mikrobiologie (DE-588)4316357-9 gnd rswk-swf Pflanzen (DE-588)4045539-7 gnd rswk-swf (DE-588)4143413-4 Aufsatzsammlung gnd-content Pflanzen (DE-588)4045539-7 s Mikrobiologie (DE-588)4316357-9 s DE-604 Varma, Ajit 1939- Sonstige (DE-588)120066718 oth Digitalisierung UB Regensburg application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016676967&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Plant surface microbiology Plant surfaces Microbiology Mikrobiologie (DE-588)4316357-9 gnd Pflanzen (DE-588)4045539-7 gnd |
| subject_GND | (DE-588)4316357-9 (DE-588)4045539-7 (DE-588)4143413-4 |
| title | Plant surface microbiology |
| title_auth | Plant surface microbiology |
| title_exact_search | Plant surface microbiology |
| title_exact_search_txtP | Plant surface microbiology |
| title_full | Plant surface microbiology Ajit Varma ... (eds.) |
| title_fullStr | Plant surface microbiology Ajit Varma ... (eds.) |
| title_full_unstemmed | Plant surface microbiology Ajit Varma ... (eds.) |
| title_short | Plant surface microbiology |
| title_sort | plant surface microbiology |
| topic | Plant surfaces Microbiology Mikrobiologie (DE-588)4316357-9 gnd Pflanzen (DE-588)4045539-7 gnd |
| topic_facet | Plant surfaces Microbiology Mikrobiologie Pflanzen Aufsatzsammlung |
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