Produktbild: Correlative Imaging

Correlative Imaging Focusing on the Future

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Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

04.11.2019

Herausgeber

Verkade Paul + weitere

Verlag

John Wiley & Sons Inc

Seitenzahl

256

Maße (L/B/H)

25.4/17.7/1.7 cm

Gewicht

658 g

Sprache

Englisch

ISBN

978-1-119-08645-1

Produktdetails

Einband

Gebundene Ausgabe

Erscheinungsdatum

04.11.2019

Herausgeber

Verlag

John Wiley & Sons Inc

Seitenzahl

256

Maße (L/B/H)

25.4/17.7/1.7 cm

Gewicht

658 g

Sprache

Englisch

ISBN

978-1-119-08645-1

Herstelleradresse

Produktsicherheitsverantwortliche/r
Europaallee 1
36244 Bad Hersfeld
DE

Email: gpsr@libri.de

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  • Produktbild: Correlative Imaging
  • List of Contributors xi

    Preface xiii

    1 It's a Small, Small World: A Brief History of Biological Correlative Microscopy 1
    Christopher J. Guérin, Nalan Liv, and Judith Klumperman

    1.1 It All Began with Photons 1

    1.2 The Electron Takes Its Place 2

    1.3 Putting It Together, 1960s to 1980s 3

    1.4 CLEM Matures as a Scientific Tool 1990 to 2017 4

    Acknowledgments 13

    References 13

    2 Challenges for CLEM from a Light Microscopy Perspective 23
    Kurt Anderson, Tommy Nilsson, and Julia Fernandez¿Rodriguez

    2.1 Introduction 23

    2.1.1 Electron and Light Microscopy 23

    2.1.2 Correlative Microscopy: Two Cultures Collide 25

    2.2 Microscopy Multiculturalism 26

    2.2.1 When Fluorescence Light Microscopy Resolution is Not Enough 26

    2.2.2 The Fluorescence Microscopy (FM), Needle/Haystack Localization 27

    2.2.3 Electron Microscopy, Visualizing the Ultrastructure 27

    2.2.4 Finding Coordinates 28

    2.3 Bridging the Gap between Light and Electron Microscopy 29

    2.3.1 Finding the Same Cell Structure in Light and Electron Microscopes 29

    2.3.2 Making the Fluorescence Labels Visible in the Electron Microscope 29

    2.3.3 Visualizing Membrane Trafficking Using CLEM 30

    2.4 Future CLEM Applications and Modifications 31

    2.4.1 Correlative Reflection Contrast Microscopy and Electron Microscopy in Tissue Sections 31

    2.4.2 Dynamic and Functional Probes for CLEM 32

    References 34

    3 The Importance of Sample Processing for Correlative Imaging (or, Rubbish In, Rubbish Out) 37
    Christopher J. Peddie and Nicole L. Schieber

    3.1 Introduction 37

    3.2 Searching for Correlative Electron Microscopy Utopia 40

    3.3 Sample Processing for Correlative Imaging: A Primer for the First Steps 40

    3.4 Making It Go Faster (We Want More Speed, More Speed...) 42

    3.5 Embedding Resins 44

    3.6 Keeping the Region of Interest in Sight 45

    3.7 Correlation and Relocation with Dual Modality Probes 48

    3.8 Integration of Imaging Modalities, and In¿Resin Fluorescence 49

    3.9 Streamlining the Correlative Approaches of the Future: SmartCLEM 51

    3.10 How Deep Does the Rabbit Hole Go? 52

    3.11 Hold That Thought, Though ¿ Is This All Completely Necessary? 53

    3.12 Improving Accessibility to Correlative Workflows 54

    3.13 Coming to the End 55

    References 55

    4 3D CLEM: Correlating Volume Light and Electron Microscopy 67
    Saskia Lippens and Eija Jokitalo

    4.1 Introduction 67

    4.2 Imaging in 3D 68

    4.3 Comparative and Correlative LM and EM Imaging 69

    4.4 CLEM is More than LM + EM 69

    4.5 3D CLEM 70

    4.6 Two Workflows for 3D CLEM 71

    4.7 Where is CLEM Going in the Future? 74

    Acknowledgments 76

    References 77

    5 Can Correlative Microscopy Ever Be Easy? An Array Tomography Viewpoint 81
    Irina Kolotuev and Kristina D. Micheva

    5.1 Introduction 81

    5.2 Why Array Tomography? 81

    5.3 Array Tomography of Abundant Subcellular Structures: Synapses 82

    5.4 Array Tomography of Sparsely Distributed Structures: Cisternal Organelle 84

    5.5 Array Tomography of Small Model Organisms: C. elegans 87

    5.6 To Summarize: Finding the Right AT Approach 90

    5.7 Areas of Improvement 91

    5.7.1 Resin 91

    5.7.2 Serial Ultrathin Sectioning 91

    5.7.3 Antibodies 92

    5.7.4 EM Compatible Fluorophores 92

    5.7.5 Detectors and EM Resolution 92

    5.7.6 Image Registration and Alignment Tools 93

    5.7.7 Data Sharing 93

    5.7.8 "Dream" Resource 93

    5.7.9 Dream Experiments 94

    Acknowledgments 95

    References 95

    6 Correlative Microscopy Using Scanning Probe Microscopes 99
    Georg Fantner and Frank Lafont

    6.1 Introduction 99

    6.2 Principles of AFM 100

    6.3 AFM and Optical Microscopy Correlative Approaches 103

    6.4 Correlation with CLSM 104

    6.5 Correlation with Cell Mechanics 104

    6.5.1 Correlation with Super¿Resolution Light Microscopy (SRLM) 105

    6.5.2 Future Developments 107

    6.6 AFM and Correlation with Electron Microscopy 109

    6.6.1 Correlation Involving AFM, EM, and Chemical Surface Characterization 110

    6.6.2 Future Developments 113

    6.7 Future Developments Involving Correlation Microscopy Using HS¿AFM 113

    6.8 Concluding Remarks 114

    Acknowledgments 114

    References 115

    7 Integrated Light and Electron Microscopy 119
    R. I. Koning, A. Srinivasa Raja, R. I. Lane, A. J. Koster, and J. P. Hoogenboom

    7.1 Introduction 119

    7.2 Large¿Scale and High¿Throughput (Volume) Microscopy 120

    7.2.1 Advantages and Challenges for Large¿Scale EM 120

    7.2.2 Advantages of CLEM for Large¿Scale EM 121

    7.2.3 Prospects for Integrated Microscopy 121

    7.3 Super¿Resolution Fluorescence Microscopy 123

    7.3.1 Advantages and Challenges for CLEM with Super¿Resolution Fluorescence 123

    7.3.2 Implementation of SR¿FM with CLEM 124

    7.3.3 Prospects for Integrated SR¿CLEM 124

    7.4 CryöElectron Microscopy 125

    7.4.1 Advantages of CryoEM 125

    7.4.2 Possibilities and Challenges for Correlative CryöMicroscopy 126

    7.4.2.1 Super¿Resolution Fluorescence CryöMicroscopy: Probes and Instruments 126

    7.4.2.2 Transfer of CryöSamples between Microscopes 127

    7.4.2.3 Sample Thickness 127

    7.4.2.4 Data Collection Speed 128

    7.4.3 Integrated Systems for CryoCLEM 129

    7.4.4 Prospects for Integrated CryöMicroscopy 129

    7.5 Outlook 130

    Acknowledgments 131

    References 131

    8 CryöCorrelative Light and Electron Microscopy: Toward in situ Structural Biology 137
    Tanmay A.M. Bharat and Wanda Kukulski

    8.1 Introduction 137

    8.2 CryöCLEM to Support Single Particle Analysis of Purified Macromolecules 138

    8.3 Capturing Structural Dynamics of in vitro Reconstituted Systems 141

    8.4 Identifying Macromolecules in Plunge¿Frozen Whole Cells 142

    8.5 Macromolecular Structures in Thinned Samples from Thick Cell Areas 144

    8.6 Enabling Structural Biology in Multicellular Organisms and Tissues by CryöCLEM 145

    8.7 Conclusions 147

    Acknowledgments 147

    References 147

    9 Correlative Cryo Soft X¿ray Imaging 155
    Eva Pereiro, Francisco Javier Chichón, and Jose L. Carrascosa

    9.1 Introduction to Cryo Soft X¿ray Microscopy 155

    9.2 CryöSXT Correlation with Visible Light Microscopy 159

    9.3 CryöSXT Correlation with Cryo X¿ray Fluorescence 160

    9.4 CryöSXT Correlation with TEM 163

    9.5 Multiple Correlation and Integration of Methods 165

    Acknowledgments 165

    References 166

    10 Correlative Light¿ and Liquid¿Phase Scanning Transmission Electron Microscopy for Studies of Protein Function in Whole Cells 171
    Niels de Jonge

    10.1 Introduction 171

    10.2 Limitations of State¿of¿the¿Art Methods 172

    10.3 Principle of Liquid STEM 173

    10.3.1 Example 1: Determination of ORAI Channel Subunit Stoichiometry by Visualizing Single Molecules Using STEM 175

    10.3.1.1 Conclusions 179

    10.3.2 Example 2: New Insights into the Role of HER2 179

    10.3.2.1 Conclusions 182

    10.4 Advantages of Liquid STEM 182

    10.5 Future Prospects 184

    Acknowledgments 185

    References 185

    11 Correlating Data from Imaging Modalities 191
    Perrine Paul¿Gilloteaux and Martin Schorb

    11.1 Introduction 191

    11.2 Registration during CLEM Stages 194

    11.2.1 Registration to Guide Sample Preparation 194

    11.2.2 Registration to Guide the Acquisition 195

    11.2.2.1 Software Packages 195

    11.2.2.2 Typical Features and Fields of View 195

    11.2.3 Post¿Acquisition Registration (Accurate Relocation) 196

    11.2.3.1 Software and Approaches for Post¿Acquisition Registration 196

    11.2.4 Trust in Alignment: Accuracy in Practice 198

    11.3 Registration Paradigm 198

    11.3.1 Image Features to Guide the Registration 198

    11.3.2 Distance Function 199

    11.3.3 Transformation Basis 199

    11.3.4 Optimization Strategy 200

    11.4 Envisioned Future Developments 201

    11.4.1 Integrative Microscopy versus Correlative Microscopy 201

    11.4.2 Incorporate a Priori Knowledge of the Specimen 202

    11.4.3 Toward the Use of Machine Learning 202

    11.5 Visualization of Correlation 204

    11.6 Conclusion 204

    Acknowledgments 205

    References 205

    12 Big Data in Correlative Imaging 211
    Ardan Patwardhan and Jason R. Swedlow

    12.1 Introduction 211

    12.2 The Protein Data Bank 212

    12.3 Resources for CryöEM 212

    12.4 Light Microscopy Data Resources 214

    12.5 EMPIAR 215

    12.6 IDR: A Prototype Image Data Resource 216

    12.7 Public Resources for Correlative Imaging 217

    12.7.1 CLEM Data Formats 217

    12.8 Future Directions 218

    12.8.1 A BioImage Archive 218

    12.8.2 CLEM Data Submission Pipelines 219

    12.8.3 Scaling Data Volumes and Usage 219

    12.8.4 Community Adoption and International Engagement 220

    Acknowledgments 220

    References 221

    13 The Future of CLEM: Summary 223
    Lucy Collinson and Paul Verkade

    Index 227