Publication date from publishers website.

Includes bibliographical references and index.

1 Introduction to Cell Biology 1

1.1 The Discovery of Cells 2

1.2 Basic Properties of Cells 3

1.3 Two Fundamentally Different Classes of Cells 8

1.4 Types of Prokaryotic Cells 14

1.5 Types of Eukaryotic Cells 15

1.6 The Sizes of Cells and Their Components 18

1.7 Viruses 19

THE HUMAN PERSPECTIVE 23

The Prospect of Cell Replacement Therapy 23

EXPERIMENTAL PATHWAYS 27

The Origin of Eukaryotic Cells 27

2 The Structure and Functions of Biological Molecules 33

2.1 Covalent Bonds 34

2.2 Noncovalent Bonds 36

2.3 Acids, Bases, and Buffers 39

2.4 The Nature of Biological Molecules 40

2.5 Carbohydrates 42

2.6 Lipids 47

2.7 Building Blocks of Proteins 49

2.8 Primary and Secondary Structures of Proteins 54

2.9 Tertiary Structure of Proteins 56

2.10 Quaternary Structure of Proteins 60

2.11 Protein Folding 61

2.12 Proteomics and Interactomics 64

2.13 Protein Engineering 67

2.14 Protein Adaptation and Evolution 69

2.15 Nucleic Acids 71

2.16 The Formation of Complex Macromolecular Structures 72

THE HUMAN PERSPECTIVE 73

I. Do Free Radicals Cause Aging? 73

II. Protein Misfolding Can Have Deadly Consequences 74

EXPERIMENTAL PATHWAYS 79

Chaperones—Helping Proteins Reach Their Proper Folded State 79

3 Bioenergetics, Enzymes, and Metabolism 87

3.1 Bioenergetics 88

3.2 Free Energy 90

3.3 Coupling Endergonic and Exergonic Reactions 94

3.4 Equilibrium versus Steady]State Metabolism 94

3.5 Enzymes as Biological Catalysts 95

3.6 Mechanisms of Enzyme Catalysis 99

3.7 Enzyme Kinetics 103

3.8 Metabolism 106

3.9 Glycolysis and ATP Production 108

3.10 Reducing Power 112

3.11 Metabolic Regulation 113

3.12 Separating Catabolic and Anabolic Pathways 114

THE HUMAN PERSPECTIVE 115

I. The Growing Problem of Antibiotic Resistance 115

II. Caloric Restriction and Longevity 118

4 Genes, Chromosomes, and Genomes 123

4.1 The Concept of a Gene as a Unit of Inheritance 124

4.2 The Discovery of Chromosomes 125

4.3 Chromosomes: The Physical Carriers of the Genes 126

4.4 Genetic Analysis in Drosophila 127

4.5 The Structure of DNA 129

4.6 DNA Supercoiling 134

4.7 The Structure of the Genome 136

4.8 The Stability of the Genome 141

4.9 "Jumping Genes" and the Dynamic Nature of the Genome 143

4.10 Sequencing Genomes: The Footprints of Biological Evolution 146

4.11 Comparative Genomics: "If It's Conserved, It Must Be Important" 148

4.12 The Genetic Basis of "Being Human" 148

4.13 Genetic Variation within the Human Species Population 150

THE HUMAN PERSPECTIVE 152

I. Diseases That Result from Expansion of Trinucleotide Repeats 152

II. Application of Genomic Analyses to Medicine 154

EXPERIMENTAL PATHWAYS 157

The Chemical Nature of the Gene 157

5 The Path to Gene Expression 165

5.1 The Relationship between Genes, Proteins, and RNAs 166

5.2 The Role of RNA Polymerases in Transcription 169

5.3 An Overview of Transcription in Both Prokaryotic and Eukaryotic Cells 171

5.4 Synthesis and Processing of Eukaryotic Ribosomal and Transfer RNAs 174

5.5 Synthesis and Structure of Eukaryotic Messenger RNAs 178

5.6 Split Genes: An Unexpected Finding 181

5.7 The Processing of Eukaryotic Messenger RNAs 184

5.8 Evolutionary Implications of Split Genes and RNA Splicing 189

5.9 Creating New Ribozymes in the Laboratory 191

5.10 Small Regulatory RNAs and RNA Silencing Pathway 191

5.11 Small RNAs: miRNAs and piRNAs 193

5.12 CRISPR and other Noncoding RNAs 195

5.13 Encoding Genetic Information 196

5.14 Decoding the Codons: The Role of Transfer RNAs 198

5.15 Translating Genetic Information: Initiation 201

5.16 Translating Genetic Information: Elongation and Termination 205

5.17 mRNA Surveillance and Quality Control 208

5.18 Polyribosomes 209

THE HUMAN PERSPECTIVE 210

Clinical Applications of RNA Interference 210

EXPERIMENTAL PATHWAYS 212

The Role of RNA as a Catalyst 212

6 Controlling Gene Expression 220

6.1 Control of Gene Expression in Bacteria 221

6.2 Control of Gene Expression in Eukaryotes: Structure and Function of the Cell Nucleus 225

6.3 Chromosomes and Chromatin 230

6.4 Heterochromatin and Euchromatin 234

6.5 The Structure of a Mitotic Chromosome 238

6.6 Epigenetics: There's More to Inheritance than DNA 243

6.7 The Nucleus as an Organized Organelle 244

6.8 An Overview of Gene Regulation in Eukaryotes 247

6.9 Transcriptional Control 248

6.10 The Role of Transcription Factors in Regulating Gene Expression 252

6.11 The Structure of Transcription Factors 253

6.12 DNA Sites Involved in Regulating Transcription 256

6.13 The Glucocorticoid Receptor: An Example of Transcriptional Activation 258

6.14 Transcriptional Activation: The Role of Enhancers, Promoters, and Coactivators 259

6.15 Transcriptional Activation from Paused Polymerases 263

6.16 Transcriptional Repression 264

6.17 RNA Processing Control 267

6.18 Translational Control 269

6.19 The Role of MicroRNAs in Translational Control 273

6.20 Posttranslational Control: Determining Protein Stability 274

THE HUMAN PERSPECTIVE 275

Chromosomal Aberrations and Human Disorders 275

7 DNA Replication and Repair 282

7.1 DNA Replication 283

7.2 DNA Replication in Bacterial Cells 286

7.3 The Machinery Operating at the Replication Fork 291

7.4 The Structure and Functions of DNA Polymerases 293

7.5 Replication in Viruses 296

7.6 DNA Replication in Eukaryotic Cells 296

7.7 Chromatin Structure and Replication 300

7.8 DNA Repair 302

7.9 Between Replication and Repair 305

THE HUMAN PERSPECTIVE 306

Consequences of DNA Repair Deficiencies 306

8 Cellular Membrane 311

8.1 Introduction to the Plasma Membrane 312

8.2 The Chemical Composition of Membranes 315

8.3 Membrane Carbohydrates 319

8.4 The Structure and Functions of Membrane Proteins 320

8.5 Studying the Structure and Properties of Integral Membrane Proteins 323

8.6 Membrane Lipids and Membrane Fluidity 327

8.7 The Dynamic Nature of the Plasma Membrane 329

8.8 The Red Blood Cell: An Example of Plasma Membrane Structure 334

8.9 The Movement of Substances across Cell Membranes 336

8.10 Diffusion through the Lipid Bilayer 338

8.11 The Diffusion of Ions through Membranes 340

8.12 Facilitated Diffusion 345

8.13 Active Transport 346

8.14 Membrane Potentials 350

8.15 Propagation of Action Potentials as an Impulse 353

8.16 Neurotransmission: Jumping the Synaptic Cleft 354

THE HUMAN PERSPECTIVE 357

Defects in Ion Channels and Transporters as a Cause of Inherited Disease 357

EXPERIMENTAL PATHWAYS 359

The Acetylcholine Receptor 359

9 Mitochondrion and Aerobic Respiration 368

9.1 Mitochondrial Structure and Function 369

9.2 Oxidative Metabolism in the Mitochondrion 372

9.3 The Role of Mitochondria in the Formation of ATP 377

9.4 Electron]Transport Complexes 381

9.5 Translocation of Protons and the Establishment of a Proton] Motive Force 385

9.6 The Machinery for ATP Formation 386

9.7 The Binding Change Mechanism of ATP Formation 388

9.8 Using the Proton Gradient 391

9.9 Peroxisomes 392

THE HUMAN PERSPECTIVE 394

I. The Role of Anaerobic and Aerobic Metabolism in Exercise 394

II. Diseases that Result from Abnormal Mitochondrial or Peroxisomal Function 395

10 Chloroplast and Photosynthesis 401

10.1 The Origin of Photosynthesis 402

10.2 Chloroplast Structure and Function 403

10.3 An Overview of Photosynthetic Metabolism 404

10.4 The Absorption of Light 405

10.5 Photosynthetic Units and Reaction Centers 407

10.6 The Operations of Photosystem II and Photosystem I 409

10.7 An Overview of Photosynthetic Electron Transport 413

10.8 Photophosphorylation 415

10.9 Carbon Dioxide Fixation and the Carbohydrate Synthesis 415

10.10 Carbohydrate Synthesis in C4 and CAM Plants 420

THE HUMAN PERSPECTIVE 421

Global Warming and Carbon Sequestration 421

11 The Extracellular Matrix and Cell Interactions 426

11.1 Overview of Extracellular Interactions 427

11.2 The Extracellular Space 428

11.3 Components of the Extracellular Matrix 430

11.4 Dynamic Properties of the Extracellular Matrix 435

11.5 Interactions of Cells with Extracellular Materials 436

11.6 Anchoring Cells to Their Substratum 438

11.7 Interactions of Cells with Other Cells 441

11.8 Adherens Junctions and Desmosomes: Anchoring Cells to Other Cells 445

11.9 The Role of Cell]Adhesion Receptors in Transmembrane Signaling 447

11.10 Tight Junctions: Sealing the Extracellular Space 447

11.11 Gap Junctions and Plasmodesmata: Mediating Intercellular Communication 449

11.12 Cell Walls 453

THE HUMAN PERSPECTIVE 455

The Role of Cell Adhesion in Inflammation and Metastasis 455

EXPERIMENTAL PATHWAYS 457

The Role of Gap Junctions in Intercellular Communication 457

12 Cellular Organelles and Membrane Trafficking 463

12.1 An Overview of the Endomembrane System 464

12.2 A Few Approaches to the Study of Endomembranes 466

12.3 The Endoplasmic Reticulum 472

12.4 Functions of the Rough Endoplasmic Reticulum 473

12.5 Membrane Biosynthesis in the Endoplasmic Reticulum 477

12.6 Glycosylation in the Rough Endoplasmic Reticulum 479

12.7 Mechanisms That Ensure the Destruction of Misfolded Proteins 481

12.8 ER to Golgi Vesicular Transport 482

12.9 The Golgi Complex 482

12.10 Types of Vesicle Transport and Their Functions 487

12.11 Beyond the Golgi Complex: Sorting Proteins at the TGN 491

12.12 Targeting Vesicles to a Particular Compartment 493

12.13 Exocytosis 496

12.14 Lysosomes 496

12.15 Plant Cell Vacuoles 498

12.16 Endocytosis 498

12.17 The Endocytic Pathway 502

12.18 Phagocytosis 505

12.19 Posttranslational Uptake of Proteins by Peroxisomes, Mitochondria, and Chloroplasts 505

THE HUMAN PERSPECTIVE 508

Disorders Resulting from Defects in Lysosomal Function 508

EXPERIMENTAL PATHWAYS 510

Receptor]Mediated Endocytosis 510

13 The Cytoskeleton 517

13.1 Overview of the Major Functions of the Cytoskeleton 518

13.2 Microtubules: Structure and Function 520

13.3 Motor Proteins: Kinesins and Dyneins 524

13.4 Microtubule]Organizing Centers (MTOCs) 527

13.5 Microtubule Dynamics 530

13.6 Cilia and Flagella: Structure and Function 534

13.7 Intermediate Filaments 541

13.8 Microfilaments 544

13.9 Myosin: The Molecular Motor of Actin Filaments 547

13.10 Muscle Contractility 552

13.11 Nonmuscle Motility 557

13.12 Cellular Motility 560

13.13 Actin]Dependent Processes During Development 564

13.14 The Bacterial Cytoskeleton 567

THE HUMAN PERSPECTIVE 568

The Role of Cilia in Development and Disease 568

EXPERIMENTAL PATHWAYS 569

I. The Step Size of Kinesin 569

II. Studying Actin]Based Motility without Cells 571

14 Cell Division 578

14.1 The Cell Cycle 579

14.2 Regulation of the Cell Cycle 581

14.3 Control of the Cell Cycle: The Role of Protein Kinases 582

14.4 Control of the Cell Cycle: Checkpoints, Cdk Inhibitors, and Cellular Responses 586

14.5 M Phase: Mitosis and Cytokinesis 588

14.6 Prophase 588

14.7 Prometaphase 594

14.8 Metaphase 596

14.9 Anaphase 598

14.10 Telophase and Cytokinesis 603

14.11 Meiosis 608

14.12 The Stages of Meiosis 610

14.13 Genetic Recombination during Meiosis 613

THE HUMAN PERSPECTIVE 615

Meiotic Nondisjunction and Its Consequences 615

EXPERIMENTAL PATHWAYS 616

The Discovery and Characterization of MPF 616

15 Cell Signaling Pathways 624

15.1 The Basic Elements of Cell Signaling Systems 625

15.2 A Survey of Extracellular Messengers and their Receptors 628

15.3 Signal Transduction by G Protein]Coupled Receptors 629

15.4 Second Messengers 632

15.5 The Specificity of G Protein]Coupled Responses 636

15.6 Regulation of Blood Glucose Levels 636

15.7 The Role of GPCRs in Sensory Perception 640

15.8 Protein]Tyrosine Phosphorylation as a Mechanism for Signal Transduction 641

15.9 The Ras]MAP Kinase Pathway 645

15.10 Signaling by the Insulin Receptor 648

15.11 Signaling Pathways in Plants 651

15.12 The Role of Calcium as an Intracellular Messenger 651

15.13 Convergence, Divergence, and Cross]Talk among Different Signaling Pathways 655

15.14 The Role of NO as an Intercellular Messenger 657

15.15 Apoptosis (Programmed Cell Death) 659

THE HUMAN PERSPECTIVE 663

Disorders Associated with G Protein]Coupled Receptors 663

EXPERIMENTAL PATHWAYS 665

The Discovery and Characterization of GTP]Binding Proteins 665

16 Cancer 673

16.1 Basic Properties of a Cancer Cell 674

16.2 The Causes of Cancer 677

16.3 The Genetics of Cancer 678

16.4 An Overview of Tumor]Suppressor Genes and Oncogenes 680

16.5 Tumor]Suppressor Genes: The RB Gene 681

16.6 Tumor]Suppressor Genes: The TP53 Gene 684

16.7 Other Tumor]Suppressor Genes 687

16.8 Oncogenes 688

16.9 The Mutator Phenotype: Mutant Genes Involved in DNA Repair 691

16.10 MicroRNAs: A New Player in the Genetics of Cancer 691

16.11 The Cancer Genome 691

16.12 Gene]Expression Analysis 694

16.13 Strategies for Combating Cancer 696

16.14 Immunotherapy 696

16.15 Inhibiting the Activity of Cancer]Promoting Proteins 698

16.16 The Concept of a Cancer Stem Cell 701

16.17 Inhibiting the Formation of New Blood Vessels (Angiogenesis) 701

EXPERIMENTAL PATHWAYS 702

The Discovery of Oncogenes 702

17 Immunity 709

17.1 An Overview of the Immune Response 710

17.2 The Clonal Selection Theory as It Applies to B Cells 714

17.3 Vaccination 715

17.4 T Lymphocytes: Activation and Mechanism of Action 717

17.5 The Modular Structure of Antibodies 720

17.6 DNA Rearrangements That Produce Genes Encoding B] and T]Cell Antigen Receptors 723

17.7 Membrane]Bound Antigen Receptor Complexes 725

17.8 The Major Histocompatibility Complex 726

17.9 Distinguishing Self from Nonself 730

17.10 Lymphocytes Are Activated by Cell]Surface Signals 731

17.11 Signal Transduction Pathways in Lymphocyte Activation 732

THE HUMAN PERSPECTIVE 733

Autoimmune Diseases 733

EXPERIMENTAL PATHWAYS 736

The Role of the Major Histocompatibility Complex in Antigen Presentation 736

18 Techniques in Cell and Molecular Biology 742

18.1 The Light Microscope 743

18.2 Bright]Field and Phase]Contrast Microscopy 745

18.3 Fluorescence Microscopy (and Related Fluorescence]Based Techniques) 746

18.4 Transmission Electron Microscopy 752

18.5 Specimen Preparation for Electron Microscopy 753

18.6 Scanning Electron Microscopy 757

18.7 Atomic Force Microscopy 758

18.8 The Use of Radioisotopes 759

18.9 Cell Culture 760

18.10 The Fractionation of a Cell's Contents by Differential Centrifugation 762

18.11 Purification and Characterization of Proteins by Liquid Column Chromatography 762

18.12 Determining Protein–Protein Interactions 764

18.13 Characterization of Proteins by

18.14 Characterization of Proteins by Spectrometry 767

18.15 Characterization of Proteins by Mass Spectrometry 767

18.16 Determining the Structure of Proteins and Multisubunit Complexes 768

18.17 Fractionation of Nucleic Acids 770

18.18 Nucleic Acid Hybridization 773

18.19 Chemical Synthesis of DNA 774

18.20 Recombinant DNA Technology 774

18.21 Enzymatic Amplification of DNA by PCR 778

18.22 DNA Sequencing 780

18.23 DNA Libraries 782

18.24 DNA Transfer into Eukaryotic Cells and Mammalian Embryos 783

18.25 Gene Editing and Silencing 786

18.26 The Use of Antibodies 789

Karp’s Cell Biology, Global Edition continues to build on its strength at connecting key concepts to the experiments that reveal how we know what we know in the world of Cell Biology. This classic text explores core concepts in considerable depth, often adding experimental detail. It is written in an inviting style to assist students in handling the plethora of details encountered in the Cell Biology course. In this edition, two new co-authors take the helm and help to expand upon the hallmark strengths of the book, improving the student learning experience.