Advanced Delivery and Therapeutic Applications of Rnai

Professor Kun Cheng, Division of Pharmaceutical Sciences, School of Pharmacy, University of Missouri-Kansas City, USA
Professor Cheng's research interests include the delivery and therapeutic applications of RNAi for breast cancer, prostate cancer, liver diseases, and type I diabetes. He has been working in the area of nucleic acids since 2002. He is co-editor of Advanced Drug Delivery with Dr. Ashim Mitra and Dr. Chi Lee (Wiley, 2012). He has also co-edited a themed issue entitled "siRNA Delivery" with Dr. Ram Mahato for the journal Molecular Pharmaceutics, and has developed and taught a graduate course entitled "Protein and Nucleic Acid Drug Delivery".

Professor Ram I. Mahato, Department of Pharmaceutical Sciences, School of Pharmacy, University of Tennessee Health Science Center, USA
Professor Mahato is a full professor of Pharmaceutics and Drug/Gene Delivery at the University of Tennessee Health Science Center Memphis. He is the author or co-author of 85 peer reviewed articles and book chapters. He has also edited/written five books and six special journal issues. He is a Special Features Editor of Pharmaceutical Research and on the editorial board of several journals. His research interest includes delivery and targeting of small molecules, oligonucleotides, siRNA and genes.

Contributors xix

About the Editors xxiii

Part 1 Introduction and Basics of RNAi 1

1 Mechanisms and Barriers to RNAi Delivery 3
Jiehua Zhou and John J. Rossi

1.1 Introduction 3

1.2 Barriers to Systemic RNAi Delivery 5

1.3 Rational Design to Improve RNAi Efficacy 6

1.4 Chemical Modifications to Enhance siRNA Stability and Reduce Immune Response 7

1.5 Cellular Uptake and Intracellular Release of siRNA 7

1.6 Combinatorial Targeting for Targeted RNAi Delivery 8

1.7 Cell-Specific Aptamer-Functionalized Nanocarriers for RNAi Delivery 9

1.8 The Clinical Development and Challenges of siRNAs Therapeutics 10

1.9 Conclusion and Perspectives 12

References 12

Analysis of siRNA Delivery Using Various Methodologies 19
Yi Pei

2.1 Introduction 19

2.2 Checkpoints for Analyzing siRNA Delivery 20

2.2.1 Circulation Checkpoint 22

2.2.2 Organ or Tissue Checkpoint 22

2.2.3 Cellular Checkpoint 22

2.2.4 RISC Checkpoint 23

2.2.5 Target mRNA Knockdown (Indirect Checkpoint) 24

2.2.6 Protein and Outcome (Indirect Checkpoint) 25

2.2.7 Safety (Indirect Checkpoint) 26

2.3 Methods for Analysis of siRNA 26

2.3.1 General Considerations 26

2.3.2 Hybridization-Based (Non-Imaging) Methods 28

2.3.3 Non-Hybridization-Based (Non-Imaging) Methods 34

2.3.4 Imaging-Based (Non-Hybridization) Methods 35

2.3.5 Imaging-Based (Hybridization) Methods 37

2.4 Case Study for siRNA Delivery Analysis 38

References 39

3 Challenges and Opportunities in Bringing RNAi Technologies from Bench to Bed 45
Sandesh Subramanya and Lance Ford

3.1 Introduction 45

3.2 RNAi Mediator (siRNA or shRNA) 45

3.2.1 siRNA 45

3.2.2 Vector-derived shRNA 47

3.2.3 miRNAs 49

3.3 Safety Issues of RNAi Mediators 50

3.3.1 Immune Stimulation 50

3.3.2 RNAi Over expression 52

3.4 Efficacy of RNAi Mediators 52

3.4.1 Therapeutic Response 52

3.5 RNAi Mediators in Clinical Trials 53

3.6 Conclusion 54

References 55

Nonclinical Safety Assessments and Clinical Pharmacokinetics for Oligonucleotide Therapeutics: A Regulatory Perspective 63
Shwu-Luan Lee, Paul Brown, Jian Wang and Robert T. Dorsam

4.1 Introduction 63

4.2 Unique Properties of Oligonucleotide-based Therapeutics 63

4.3 Regulation of Oligonucleotide-Based Therapeutics 65

4.3.1 Submission to the FDA 65

4.3.2 Review Process for Non-clinical Studies 67

4.3.3 Regulatory Issues 74

4.3.4 Clinical Pharmacokinetics 76

4.4 Conclusion 79

Disclaimer 79

Appendix 79

References 80

Role of Promoters and MicroRNA Backbone for Efficient Gene Silencing 83
Feng Li and Ram I. Mahato

5.1 Introduction 83

5.2 Promoters for shRNA Expression 84

5.2.1 Constitutive Promoters 84

5.2.2 Inducible Promoters 87

5.2.3 Site Specific Promoters 93

5.3 miRNA-based shRNAs 96

5.3.1 miRNA-based shRNA Enhances Gene Silencing 96

5.3.2 miRNA-based shRNA Reduces Toxicities 97

5.3.3 Application of miRNA-based shRNA for Combination Gene Therapy 98

5.4 Concluding Remarks 100 References 101

Part 2 RNAi Delivery Strategies 109

6 Bioconjugation of siRNA for Site-specific Delivery 111
Bin Qin, Wei Jin and Kun Cheng

6.1 Introduction 111

6.2 Conjugation Strategy 112

6.2.1 RNA Chemical Modification 112

6.2.2 Site of Conjugation 114

6.2.3 Conjugation Chemistry 115

6.3 Bioconjugates for Site-specific Delivery 120

6.3.1 Antibody-siRNA Bioconjugates 120

6.3.2 Aptamer-siRNA Bioconjugates 122

6.3.3 Peptide-siRNA Bioconjugates 124

6.3.4 Lipid-siRNA Bioconjugates 126

6.3.5 Others 128

6.4 Conclusion 129

References 129

7 Multifunctional RNAi Delivery Systems 137
China Malakondaiah Kummitha, Anthony S. Malamas and Zheng-Rong Lu

7.1 Introduction 137 7.1.1 Chapter Objectives 139

7.2 Lipid-Based Delivery Systems 139

7.2.1 Cationic Lipids 139

7.2.2 Ionizable Cationic Lipids 140

7.2.3 Lipid-Like Materials 140

7.2.4 pH-sensitive Surfactants as Multifunctional siRNA Carriers 142

7.3 Polymeric Multifunctional siRNA Delivery Systems 150

7.3.1 Polyethylenimine 150

7.3.2 Chitosan 151

7.3.3 Cyclodextrins 152

7.3.4 Dendrimers 152

7.3.5 Polyalkylacrylic Acid-based pH-sensitive Polymers 153

7.3.6 Other pH-sensitive Polymers 156

7.4 Conclusion 157

References 157

8 Dendrimers in RNAi Delivery 163
Jose Luis Jimenez Fuentes, Paula Ortega, Sara Ferrando-Martýnez, Rafael Gomez, Manuel Leal, Javier de la Mata and MaAngeles Munoz-Fernandez

8.1 Introduction 163

8.2 Challenges in RNAi Delivery 164

8.3 Dendrimers as Non Viral Vectors 166

8.3.1 Dendritic Architectures 166

8.3.2 Synthesis of Dendrimers 168

8.3.3 Types of Dendrimers in Drug Delivery 169

9 Development of Pharmaceutically Adapted Mesoporous Silica Nanoparticles for siRNA Delivery 187
Wilson X. Mai, Tian Xia and Huan Meng

9.1 Introduction 187

9.2 Mesoporous Silica Nanoparticles as Novel Inorganic Nanocarriers for siRNA Delivery 188

9.2.1 Discovery and Synthesis 188

9.2.2 Surface Modification of MSNP for Nucleic Acid Delivery 190

9.2.3 MSNP for Dual siRNA and Drug Delivery 191

9.2.4 Improving in vivo Implementation of MSNP-Based Delivery Platform 196

9.2.5 Design of Pharmaceutically Adapted MSNP via the Knowledge Generated by Discoveries at the Nano/Bio Interface 197

9.3 Safety Assessment of Nanocarrier and Design of Safe MSNP Carrier 199

9.3.1 Safety of Nanocarriers 199

9.3.2 Safe Design of MSNP Carrier 201

References 179

9.4 Summary References 202

10 Environmentally-Responsive Nanogels for siRNA Delivery 207
Atsushi Tamura and Yukio Nagasaki

10.1 Introduction 207

10.1.1 siRNA Delivery System 207

10.1.2 Crosslinked Nanogels for siRNA Delivery 208

10.2 Reductive Environment-Responsive Disulfide Crosslinked Nanogels 209

10.3 Temperature-Responsive Nanogels 211

10.4 pH-Responsive Nanogels 212

10.4.1 Acid-degradable Nanogels for Intracellular Release of siRNA 212

10.4.2 Design of pH-Responsive PEGylated Nanogels with Endosomal Escape Ability 212

10.4.3 Cytoplasmic Delivery of PEGylated Nanogel/siRNA Complexes 214

10.5 PEGylated and Partially Quaternized Polyamine Nanogels 216

10.5.1 Design of Quaternized Polyamine Nanogels 216

10.5.2 Enhanced Cellular Uptake of siRNA by Quaternized Polyamine Nanogels 216

10.5.3 Enhanced Gene-Silencing Activity of Quaternized Polyamine Nanogel/siRNA Complexes 219

10.6 Conclusions 220

References 220

11 Viral-Mediated Delivery of shRNA and miRNA 225
Fredric P. Manfredsson

11.1 Introduction 225

11.2 RNAi – A Brief Overview 226

11.3 shRNA or miRNA? 226

11.4 Rational Design 227

11.5 Viral Vectors 227

11.5.1 Recombinant Adeno-associated Virus (rAAV) 229

11.5.2 Retrovirus (RV) 230

11.5.3 Lentivirus (LV) 230

11.5.4 Adenovirus (AD) 231

11.5.5 Herpes Simplex Virus (HSV) 231

11.5.6 Baculovirus (BV) 232

11.5.7 Poxvirus 232

11.6 Tissue-specific Transduction 233

11.6.1 CNS 233

11.6.2 Ocular 234

11.6.3 Respiratory System 235

11.6.4 Liver 236

11.6.5 Skeletal Muscle 237

11.6.6 Heart 237

11.6.7 Systemic 238

11.6.8 Ex Vivo 238

11.6.9 Cell Culture 238

11.6.10 Transcription Cassettes 239

11.7 Applications of Virally Expressed shRNAs 241

11.7.1 Virally Mediated “Knockouts” 241

11.7.2 Concomitant Expression of Therapeutic Genes 241

11.8 Viral Gene Therapy in the Clinic 241

11.9 Conclusion 242

References 242

12 The Control of RNA Interference with Light 255
Simon H. Friedman

12.1 Introduction 255 12.2 The Importance of Gene Expression 255

12.3 Light Control of Gene Expression 257

12.4 Why Use RNA Interference as a Basis for Light Control of Gene Expression? 258

12.5 Light Activated RNA Interference (LARI), the work of Friedman and Co-Workers 259

12.6 Work of McMaster and Co-Workers, 50 Antisense Phosphate Block 262

12.7 Work of Heckel and Co-Workers, Nucleobase Block 263

12.8 Use of 20 FsiRNA, work of Monroe and Co-Workers 264

12.9 Photochemical Internalization 265

12.10 Future Directions and Conclusions 266

Acknowledgments 267

References 267

Part 3 Applications of RNAi in Various Diseases 269

13 RNAi in Cancer Therapy 271
Cristian Rodriguez-Aguayo, Arturo Chavez-Reyes, Gabriel Lopez-Berestein and Anil K. Sood

13.1 Introduction 271

13.2 Therapeutic Opportunities for Noncoding RNAs 274

13.3 RNAs as Drugs 277

13.4 Overcoming Anatomical and Physiologic Barriers 278

13.4.1 Intravascular Degradation 279

13.4.2 Tissue and Intracellular Delivery 280

13.4.3 Immune-mediated Toxic Effects 281

13.4.4 Nanocarrier-mediated Toxic Effects 282

13.5 Advanced Delivery 283

13.5.1 Localized siRNA Delivery 285

13.5.2 Systemic siRNA Delivery 288

13.5.3 Targeted siRNA Delivery 291

13.5.4 Monitoring Delivery and Therapeutic Response 293

13.6 Clinical Experience 294

13.7 The Next Steps 298

Acknowledgments 298

References 298

14 Adenovirus-mediated siRNA Delivery to Cancer 309
Chae-Ok Yun

14.1 Introduction 309

14.1.1 shRNA-expressing Vectors 310

14.1.2 Adenovirus Vectors 311

14.2 shRNA-expressing Adenoviruses: Cancer Biological Studies and Therapeutic Implications 312

14.2.1 Oncogene-targeted shRNA-expressing Ads 312

14.2.2 shRNA-expressing Adenoviruses that Target Anti-apoptotic Genes 314

14.3 Exploiting Oncolytic Adenovirus for siRNA Expression 315

14.4 Current Limitations of Adenovirus-mediated siRNA Therapy and Future Directions: Smart Adenovirus Nanocomplexes Expressing siRNA for Systemic Administration 318

14.5 Conclusion 320

References 321

15 RNAi in Liver Diseases 327
Jiang Li, Jianqin Lu, Yifei Zhang, Mohammed Ghazwani, Peng Zhang, Xiang Gao and Song Li

15.1 Introduction 327

15.2 RNAi in Viral Hepatitis 327

15.2.1 Hepatitis B 328

15.2.2 RNAi of HBV Infection via siRNA/shRNA 329

15.2.3 RNAi of HBV Infection via miRNAs 330

15.2.4 Hepatitis C 332

15.2.5 RNAi of HCV Infection via siRNA/shRNA 333

15.2.6 RNAi of HCV Infection via miRNAs 335

15.3 RNAi in Hepatocellular Carcinoma 336

15.3.1 RNAi of HCC via siRNA/shRNA 337

15.3.2 RNAi of HCC via miRNAs 338

15.4 RNAi in Liver Fibrosis 340

15.4.1 RNAi of Liver Fibrosis via siRNA/shRNA 341

15.4.2 RNAi of Liver Fibrosis via miRNAs 343

15.5 Delivery Systems in RNAi 345

15.5.1 Liver Anatomy 346

15.5.2 Viral Delivery Systems 346

15.5.3 Non-Viral Delivery Systems 347

15.5.4 Cell-specific Targeting Strategies 348

15.5.5 Cellular Events after the Uptake of Nucleic Acid-Carrier Complexes 349

15.5.6 Lipid-based Delivery Systems 350

15.5.7 Polymer-Based Systems 350

15.5.8 Calcium Phosphate-Lipid Hybrid System 351

15.5.9 Hydrophobitized Nucleic Acid Derivatives 351

15.5.10 Targeted Delivery to Tumor Blood Vessels 351

15.6 Conclusion 352

Acknowledgments 353

References 353

16 Approaches to Delivering RNAi Therapeutics that Target Hepatitis B Virus 367
Carol Crowther, Mohube Betty Mowa, Abdullah Ely and Patrick Arbuthnot

16.1 Introduction 367

16.1.1 RNAi Therapeutics 368

16.1.2 Hepatitis B Virus as a Target for RNAi-based Gene Silencing 369

16.2 Vectors Suitable for Hepatic Delivery of HBV Gene Silencers 369

16.2.1 Viral Vectors 370

16.2.2 Nonviral Vectors 377

16.3 Conclusions 381

Acknowledgments 382

References 382

17 RNAi in Respiratory Diseases 391
Ciara Kelly, Awadh B. Yadav, Paul J. McKiernan, Catherine M. Greene and Sally-Ann Cryan

17.1 Introduction 391

17.2 Respiratory Disease and RNA Interference 392

17.2.1 RNAi in Lung Cancer 393

17.2.2 RNAi to Treat Respiratory Infections 393

17.2.3 RNAi in Inflammatory Lung Disease 394

17.3 Delivery and Development of RNAi Therapies for Respiratory Disease 397

17.3.1 Inhalation of RNA-medicines 397

17.3.2 Chemical Modifications of siRNA 399

17.3.3 RNAi Vectors 400

17.3.4 RNAi Therapy In Vivo 405

17.4 Conclusions 408

Acknowledgements 408 References 408

18 RNAi in Ocular Diseases 417
Andrey Turchinovich, Georg Zoidl and Rolf Dermietzel

18.1 Introduction 417

18.2 The Principle of RNAi 418

18.3 In vivo Delivery of siRNA 419

18.4 Delivery of siRNA into the Eye 420

18.4.1 Routes for Ocular Delivery of siRNA 420

18.4.2 Delivery of Naked siRNA 421

18.4.3 Delivery of siRNA Using Carriers 425

18.4.4 Viral Delivery of shRNA 429

18.5 Conclusions 431

Abbreviations 432

References 432

19 micro RNAs as Therapeutic Agents and Targets 439
D.S. Karolina and K. Jeyaseelan

19.1 Introduction 439

19.2 miRNA Therapeutics 440

19.2.1 Therapeutic miRNA Inhibition 443

19.2.2 Therapeutic miRNA Mimicry 446

19.3 MicroRNAs and Cancer 447

19.4 MicroRNAs in Stroke 450

19.5 MicroRNAs in Heart Diseases 452

19.6 MicroRNAs in Diabetes Mellitus 454

19.7 MicroRNAs in Liver Diseases 457

19.8 MicroRNAs and Ocular Diseases 461

19.9 MicroRNAs and Respiratory Diseases 462

19.10 MicroRNAs and Stem Cell Research 465

19.11 Conclusion 468

References 469

20 Delivery of Micro RNA Sponges for Interrogation of MicroRNA Function In Vitro and In Vivo 483
Jiakai Lin and Shu Wang

20.1 MicroRNA Loss-of-Function Studies 483

20.2 Considerations in MicroRNA Sponge Design 486

20.2.1 Vector 486

20.2.2 Promoter 487

20.2.3 Reporter Gene 488

20.2.4 MicroRNA Binding Sites 488

20.3 Advantages and Limitations of MicroRNA Sponge over Other MicroRNA Loss-of-Function Strategies 489

20.4 Interrogating MicroRNA Function via Transient MicroRNA Sponge Expression 493

20.5 Interrogating MicroRNA Function via Stable MicroRNA Sponge Expression 494

20.5.1 MicroRNA and Cell Differentiation 494

20.5.2 MicroRNAs in Disease Development 495

20.6 Utility of MicroRNA Sponge in Living Organisms 496

20.6.1 MicroRNA Knockdown in Plants 496

20.6.2 MicroRNA Knockdown in Mouse 497

20.6.3 MicroRNA Knockdown in Drosophila Melanogaster 498

20.7 Future Perspectives 498

References 499

Index 505

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