International Review of Cell and Molecular Biology (eBook)
280 Seiten
Elsevier Science (Verlag)
978-0-12-381259-9 (ISBN)
International Review of Cell ,and Molecular Biology presents current advances and comprehensive reviews in cell biology--both plant and animal. Articles address structure and control of gene expression, nucleocytoplasmic interactions, control of cell development and differentiation, and cell transformation and growth. Impact factor for 2008: 4.935.
* Authored by some of the foremost scientists in the field * Provides up-to-date information and directions for future research * Valuable reference material for advanced undergraduates, graduate students and professional scientists
International Review of Cell and Molecular Biology presents current advances and comprehensive reviews in cell biology--both plant and animal. Articles address structure and control of gene expression, nucleocytoplasmic interactions, control of cell development and differentiation, and cell transformation and growth. Impact factor for 2008: 4.935. - Authored by some of the foremost scientists in the field- Provides up-to-date information and directions for future research- Valuable reference material for advanced undergraduates, graduate students and professional scientists
Front Cover 1
International Review of Cell and Molecular Biology 4
Copyright Page 5
Contents 6
Contributors 8
Chapter 1: Interactions Between Plants and Arbuscular Mycorrhizal Fungi 10
1. Introduction 11
2. Studies on Model Legumes 12
2.1. The presymbiotic phase 12
2.2. The endosymbiotic phase 18
3. Studies on Other Plants 23
3.1. Bryophytes 23
3.2. Lessons from Arabidopsis 25
3.3. Crops 27
3.4. Variability of plant responses as to AM colonization 33
3.5. Toward sustainable agriculture 35
4. Concluding Remarks 41
Acknowledgments 42
References 42
Chapter 2: Barley Grain Development: Toward an Integrative View 58
1. Introduction 59
2. Barley Grain Development 60
3. 3-D/4-D Models of Developing Barley Grains 64
3.1. Caryopsis high-resolution 3-D models from serial sections and data integration 64
3.2. Magnetic resonance-based modeling 66
4. Omics Technologies and Molecular-Physiological Events During Grain Development 68
4.1. Transcriptome data revisited 68
4.2. Maternal influences on grain development 69
4.3. Programmed cell death in maternal tissues and endosperm 73
4.4. Endosperm transfer cells 75
4.5. Transcriptional reprograming in endosperm differentiation, seed filling, and sink strength 76
4.6. Energy provision for storage metabolism 78
4.7. Roles of hormones and transcriptional networks in differentiation and maturation of endosperm and embryo 81
5. Systems Biology View of Barley Grain Development 86
5.1. Data generation, storage, integration, and visualization for systems biology 86
5.2. Modeling 87
6. Concluding Remarks 88
Acknowledgments 90
References 90
Chapter 3: New Insights into the Regulation of the Actin Cytoskeleton by Tropomyosin 100
1. Introduction 101
2. Biochemical and Biophysical Properties of Tropomyosin 101
2.1. Gene structure 101
2.2. Protein structure 104
2.3. Biochemical properties 107
3. Roles of Tropomyosin in Muscle and Nonmuscle Cells 108
3.1. Striated muscle contraction 108
3.2. Smooth muscle 110
3.3. Tropomyosin in nonmuscle cells 111
4. Intracellular Distribution of Tropomyosin Isoforms 114
4.1. Distribution of tropomyosin isoforms 114
4.2. Interaction of actin–tropomyosin with myosin II 116
4.3. Class I myosins and tropomyosins at the cell membrane 117
5. Caldesmon and Tropomyosins 117
5.1. Relationship between tropomyosin and caldesmon 117
5.2. Phosphorylation of tropomyosin and caldesmon in cells 119
5.3. How caldesmon and tropomyosins affect actin dynamics 121
6. Potential Roles of Tropomyosin in Cancer Metastasis 123
7. Concluding Remarks 125
Acknowledgments 125
References 126
Chapter 4: Regulation of Sulfate Transport and Assimilation in Plants 138
1. Introduction 139
2. Sulfate Transport Systems 141
2.1. Uptake of sulfate 141
2.2. Root-to-shoot transport of sulfate 146
2.3. Vacuolar transport of sulfate 148
2.4. Source-to-sink transport of sulfur 149
2.5. Other transport processes 151
3. Regulation of Sulfate Transport and Metabolism 154
3.1. Effectors of regulation 154
3.2. Regulatory elements 157
4. Concluding Remarks 161
Acknowledgments 162
References 162
Chapter 5: Metabolic Pathways in the Apicoplast of Apicomplexa 170
1. Introduction 171
2. Morphology, Acquisition, and Evolutionary Origin of the Apicoplast 173
3. Genome, Proteome, and Protein Trafficking 174
4. Potential and Limitations of In Silico Predictions of Metabolic Pathways 177
5. Biosynthesis of Various Metabolites and Factors 179
5.1. Isoprenoids 179
5.2. Abscisic acid 197
5.3. Fatty acids 199
5.4. Lipoic acid 203
5.5. Iron–sulfur clusters 206
5.6. Heme 212
6. Apicoplast Metabolic Pathways as Drug Targets and the Phenomenon of Delayed Death 217
7. Conclusions 219
Acknowledgments 220
References 220
Chapter 6: Molecular Mechanisms of Pathogenesis of Parkinson's Disease 238
1. Introduction 239
2. Clinical Features of Parkinson's Disease 240
3. Neuropathology of Parkinson's Disease 242
4. Genetic Causes of Parkinson's Disease 243
4.1. Monogenic forms of Parkinson’s disease 244
4.2. Genes and biological processes involved in the pathogenesis of sporadic Parkinson’s disease 255
5. Conclusion 265
References 266
Index 276
Color Plates 282
Barley Grain Development
Toward an Integrative View
Nese Sreenivasulu*; Ljudmilla Borisjuk*; Björn H. Junker*; Hans-Peter Mock*; Hardy Rolletschek*; Udo Seiffert†; Winfriede Weschke*; Ulrich Wobus* * Leibniz Institute of Plant Genetics and Crop Plant Research, Gatersleben, Germany
† Fraunhofer Institute for Factory Operation and Automation IFF, Magdeburg, Germany
Abstract
Seeds are complex structures composed of several maternal and filial tissues which undergo rapid changes during development. In this review, the barley grain is taken as a cereal seed model. Following a brief description of the developing grain, recent progress in grain development modeling is described. 3-D/4-D models based on histological sections or nondestructive NMR measurements can be used to integrate a variety of datasets. Extensive transcriptome data are taken as a frame to augment our understanding of various molecular-physiological processes. Discussed are maternal influences on grain development and the role of different tissues (pericarp, nucellus, nucellar projection, endosperm, endosperm transfer cells). Programmed cell death (PCD) is taken to pinpoint tissue specificities and the importance of remobilization processes for grain development. Transcriptome data have also been used to derive transcriptional networks underlying differentiation and maturation in endosperm and embryo. They suggest that the “maturation hormone” ABA is important also in early grain development. Massive storage product synthesis during maturation is dependent on sufficient energy, which can only be provided by specific metabolic adaptations due to severe oxygen deficiencies within the seed. To integrate the great variety of data from different research areas in complex, predictive computational modeling as part of a systems biology approach is an important challenge of the future. First attempts of modeling barley grain metabolism are summarized.
Key Words
Barley grain development
3-D/4-D grain models
Maternal tissues
Programmed cell death
Abscisic acid
Seed maturation
Transcriptome
Metabolic modeling
Systems biology
1 Introduction
Seeds are complex structures to aid plant dispersal and hold developmental processes to withstand severe environmental conditions. They are at the same time our most important food and feed mainly derived from cereals. Among the cereals, barley is both an important crop (Baik and Ullrich, 2008) and a model for cereal genetics and genomics (Sreenivasulu et al., 2008a). Due to the economic importance and the central role in plant reproduction, numerous studies have dealt with grain development under controlled and different environmental conditions. Recent rapid development of new techniques from high-throughput genomics and postgenomics technologies to nondestructive imaging provides numerous additional data and paves the way for a much deeper understanding of the developing seed in which parallel or time-shifted interconnected physiological processes occur in different tissues. Especially, the omics technologies became the data-generating workhorses of a more holistic systems approach to seed biology. However, the exploration of cereal seed development with the new technologies is still inadequately advanced; most studies have focused on the model plant Arabidopsis. Nevertheless, we can already start to integrate genetic, molecular, biochemical, physiological, and histological data with the help of various computing tools. One tool for global data integration is the recently developed 3-D morphological grain models, extended to the fourth, the time dimension (Section 3). Such models are especially helpful since a major obstacle in the analysis of grain development is the complex nature of a grain. A detailed histological study of barley caryopsis development between anthesis and early maturation revealed at least 18 different tissues and tissue complexes (Gubatz et al., 2007) but even within a single tissue such as the endosperm biochemical and physiological gradients have been detected (Rolletschek et al., 2004). Therefore, we will place special emphasis on spatial aspects whenever data are available. Manually dissected maternal and filial barley grain tissues (Sreenivasulu et al., 2006) as well as two laser-microdissected transport-related tissues, nucellar projection (NP) and endosperm transfer cells (ETC) (Thiel et al., 2008), revealed not only extensive tissue-specific transcriptome but also biochemical data, and an in silico comparison with Arabidopsis seed tissue-specific transcriptome data (Section 4.7.3) underlined the importance of a spatially differentiated view.
Transcriptome studies unfolded a considerable potential to integrate a multitude of observations due to its global character even if the evidence provided for specific processes and regulatory networks is generally only of correlative nature. Since a single review cannot cover all relevant areas, we had to restrict ourselves to certain aspects, and we chose those that the authors have worked on during recent years with the goal to integrate molecular, biochemical, physiological, histological, and cell biology data. Besides model development, special emphasis is also placed on the molecular mechanisms and regulatory cascades influencing programmed cell death (PCD) events in different grain tissues and on processes involved in seed filling. Furthermore, first attempts to develop predictive models for barley grain metabolism are summarized. Although this review is devoted to barley grain development, we will often refer to studies on other cereals and sometimes also to evolutionary less-related plants if these data significantly broaden our view.
2 Barley Grain Development
The barley grain is a fruit in which pericarp and seed coat (testa) are fused to form a caryopsis. Its development is usually divided into three to four stages: prestorage (or cell division or morphogenesis) phase, storage (or maturation) phase, and desiccation (or late maturation) phase. Based on the massive transcriptional reprograming between prestorage and storage phase, this time span has been defined as a distinct transition or intermediate phase (Sreenivasulu et al., 2004). Gross morphological and histological changes during development of the barley grain have been described (Bethke et al., 2000; Evers and Millar, 2002; Wobus et al., 2005) and are illustrated in Fig. 2.1. In the following, we delineate grain development from fertilization to the early storage phase in some detail to better understand tissue interactions and respective molecular-physiological processes discussed later.
At the time of double fertilization, the diploid zygote together with the triploid nucleus of the central cell, the antipodal cells, and the synergids are surrounded by the maternal nucellus and embedded into the embryo sac demarcated by the inner and outer integument. At anthesis, style and pericarp/testa (for simplicity abbreviated “pericarp”) represent more than 90% of the maternal gametophyte; cells of the style contain high amounts of starch (Weschke et al., 2000). Continuous cell division in the absence of cell wall formation leads to the endosperm coenocyte (Olsen, 2001, 2004). Under defined conditions, the coencytic phase lasts for about 60 h (Engell, 1989). Between anthesis and beginning endosperm cellularization, style volume scales down and pericarp grows in most of its parts by cell division and elongation. In cells surrounding the lateral vascular bundles, storage product accumulation takes place (Weschke et al., 2000). The most endosperm-near parts of the maternal nucellus undergo PCD (D. Weier, unpublished results) followed by cellular disintegration. Only the nucellus parts facing the main vascular tissue do not disintegrate but differentiate into the NP, that maternal tissue releases nutrients into the apoplastic space between the maternal and the filial seed part. At 3 days after flowering(DAF), when cellularization of the endosperm coenocyte starts in the middle of the caryopsis opposite NP (Fig. 2.1B), cells of that region differentiate into the ETC. The process of endosperm cellularization spreads into lateral as well as central parts and is finished at about 4–5 DAF (Fig. 2.1C). Typically, endosperm cellularization is accompanied by pericarp elongation, but at the same time remobilization processes take place in dorsal cell...
Erscheint lt. Verlag | 29.4.2010 |
---|---|
Sprache | englisch |
Themenwelt | Naturwissenschaften ► Biologie ► Genetik / Molekularbiologie |
Naturwissenschaften ► Biologie ► Zellbiologie | |
Technik | |
ISBN-10 | 0-12-381259-3 / 0123812593 |
ISBN-13 | 978-0-12-381259-9 / 9780123812599 |
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