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Cell Physiology Source Book: Essentials of Membrane Biophysics 4th Edition

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Cell Physiology Source Book: Essentials of Membrane Biophysics 4th Edition PDF

Cell Physiology Source Book: Essentials of Membrane Biophysics 4th Edition

Cell Physiology Source Book: Essentials Of Membrane Biophysics 4Th Edition Pdf

By Nicholas Sperelakis

Cell Physiology Source Book: Essentials of Membrane Biophysics 4th Edition PDF gathers together a broad range of ideas and topics that define the field. It provides clear, concise, and comprehensive coverage of all aspects of cellular physiology from fundamental concepts to more advanced topics. The 4e contains substantial new material. Most chapters have been thoroughly reworked. The book includes chapters on important topics such as sensory transduction, the physiology of protozoa and bacteria, and synaptic transmission.

  • Authored by leading researchers in the field
  • Clear, concise, and comprehensive coverage of all aspects of cellular physiology, from fundamental concepts to more advanced topics
  • Full color illustrations
Table of Contents

Dedication

In Memoriam

Contributors

Foreword to the First Edition

Foreword to the Second Edition

Foreword to the Third Edition

Foreword to the Fourth Edition

Preface

Section I Biophysical Chemistry, Metabolism, Second Messengers, and Ultrastructure

Chapter 1. Biophysical Chemistry of Physiological Solutions

I Summary

II Introduction

III Structure and Properties of Water

IV Interactions Between Water and Ions

V Protons in Solution

VI Interactions Between Ions

VII Solute Transport: Basic Definitions

VIII Measurement of Electrolytes and Membrane Potential

Appendix: Thermodynamics of Membrane Transport

AII Nernst Equilibrium

BIBLIOGRAPHY

Chapter 2. Physiological Structure and Function of Proteins

I Summary

II Molecular Structure of Proteins

III Techniques for the Determination of the Structures of Proteins

IV Bulk Properties of Proteins: Proteins as Polyelectrolytes

V Relationship of Protein Structure to Function

BIBLIOGRAPHY

Chapter 3. Cell Membranes

I Summary

II The Bimolecular Lipid Membrane

III Membrane Lipids and Proteins

IV The Fluid Mosaic Model of Cell Membranes

BIBLIOGRAPHY

Chapter 4. Ionophores in Planar Lipid Bilayers

I Summary

II Ionophores

III Planar Lipid Bilayers

IV Ion Channel Properties in Planar Lipid Bilayers

V Gramicidin

BIBLIOGRAPHY

Chapter 5. Cell Structure

I Introduction

II Techniques

III Cell Theory

IV The Plasma Membrane as the Basis of Cellularity

V Nucleus

VI Endoplasmic Reticulum

VII Golgi Apparatus

VIII Lysosomes

IX Mitochondria

X Cytoskeleton

XI Cell Junctions

XII Special Tissues, Specialized Ultrastructure

Acknowledgments

BIBLIOGRAPHY

Chapter 6. Signal Transduction and Second Messengers

I What is Signal Transduction?

II General Principles

III General Types of Signal Transduction Cascades and their Components

IV Phosphorylation by Kinases and Other Post-translational Modifications

V Intracellular Signal Transduction Pathways

VI Conclusions

BIBLIOGRAPHY

Chapter 7. Calcium as an Intracellular Second Messenger

I Introduction

II Determination of Ca2+ Involvement in Physiological Processes

III Ca2+ as an Intracellular Signal

IV Creation of the Ca2+ Signal

V Mediation of the Ca2+ Signal

VI Ca2+-Calmodulin Dependent Protein Kinase II

VII Annexins: Calcium-Dependent Phospholipid-Binding Proteins

VIII Protein Kinase C

IX Current Perspectives

X Summary

BIBLIOGRAPHY

Section II Membrane Potential, Transport Physiology, Pumps, and Exchangers

Chapter 8. Diffusion and Permeability

I Summary

II Introduction

III Fick’s Law of Diffusion

IV Diffusion Coefficient

V Diffusion Across a Membrane with Partitioning

VI Permeability Coefficient

VII Electrodiffusion

VIII Special Transport Processes

IX Ussing Flux Ratio Equation

BIBLIOGRAPHY

Chapter 9. Origin of Resting Membrane Potentials

I Summary

II Introduction

III Passive Electrical Properties

IV Maintenance of Ion Distributions

V Equilibrium Potentials

VI Electrochemical Driving Forces and Membrane Ionic Currents

VII Determination of Resting Potential and Net Diffusion Potential (Ediff)

VIII Electrogenic Sodium Pump Potentials

Appendix

AII Derivation of Nernst Equation

AIII Half-Cell Potentials

AIV Constant-Field Equation Details

AV Derivation of Chord Conductance Equation

AVI Circuit Analysis Applicable to Cell Membrane

BIBLIOGRAPHY

Chapter 10. Gibbs–Donnan Equilibrium Potentials

I Summary

II Introduction

III Mechanism for Development of the Gibbs–Donnan Potential

IV Gibbs–Donnan Equilibrium

V Quantitation of the Gibbs–Donnan Potential

VI Osmotic Considerations

BIBLIOGRAPHY

Chapter 11. Mechanisms of Carrier-Mediated Transport

I Summary

II Introduction

III Electrochemical Potential

IV Carrier-Mediated Transport Mechanisms

BIBLIOGRAPHY

Chapter 12. Active Ion Transport by ATP-Driven Ion Pumps

I Summary

II Introduction

III Classes of ATP-driven Ion Pumps

IV The Albers–Post Mechanism of Ion Transport by P-type Ion Pumps

V Structures of P-type Ion Pumps

VI Beta Subunits

VII Isoforms of Pump Subunits and Subfamilies of P-type Pumps

VIII FXYD Proteins

IX Regulation of P-type ATPase Activity

X Pharmacological Inhibitors of P-type ATPases

BIBLIOGRAPHY

Chapter 13. Ca-ATPases

I Introduction

II Sarcoplasmic Reticular (SR) Ca2+-ATPase

III Other ATPases

IV Overview

Acknowledgments

BIBLIOGRAPHY

Chapter 14. Na-Ca Exchange Currents

I Summary

II Introduction

III Energetics of Na+-Ca2+ Exchange

IV Methods and Problems Associated with the Measurement of Na+-Ca2+ Exchange Current

V Isolation of Na+-Ca2+ Exchange Current

VI Ionic Dependencies of Na+-Ca2+ Exchange Current

VII Regulation of Na+-Ca2+ Exchange Current

VIII Structure of NCX and its Relationship to Function

IX The Phylogeny of the Na+-Ca2+ Exchanger

X Isoforms of the Na+-Ca2+ Exchanger

XI Current–Voltage Relationships and Voltage Dependence of Na+-Ca2+ Exchange Current

XII Mechanism of Na+-Ca2+ Exchange

XIII Na+-Ca2+ Exchange Currents During the Cardiac Action Potential

XIV Na+-Ca2+ Exchange Currents and Excitation–Contraction Coupling

BIBLIOGRAPHY

Chapter 15. Intracellular Chloride Regulation

I Introduction

II Origin of the Passive Cl− Distribution Assumption

III Passive and Non-passive Cl− Distribution Across the Plasma Membrane

IV Active Transport Mechanisms for Cl−

V Electroneutral Na+-K+-Cl− Cotransporters

VI Electroneutral K+-Cl− Cotransporters

VII Electroneutral Na+-Cl− Cotransporter

Acknowledgments

BIBLIOGRAPHY

Chapter 16. Osmosis and Regulation of Cell Volume

I Summary

II Introduction

III Water Movement Across Model Membranes

IV Mechanisms of Osmosis

V Water Movement Across Cell Membranes

VI Regulation of Cell Volume under Isosmotic Conditions

VII Regulation of Cell Volume under Anisosmotic Conditions

Acknowledgments

BIBLIOGRAPHY

Chapter 17. Intracellular pH Regulation

I Summary

II Introduction

III pH and Buffering Power

IV Intracellular pH

V Organellar pH

VI Maintenance of a Steady-State pHi

VII Active Membrane Transport of Acids and Bases

VIII Cellular Functions Affected by Intracellular pH

BIBLIOGRAPHY

Section III Membrane Excitability and Ion Channels

Chapter 18. Cable Properties and Propagation of Action Potentials

I Summary

II Introduction

III Frequency-Modulated Signals

IV Cable Properties

V Conduction of Action Potentials

VI External Recording of Action Potentials

Appendix 1 Additional Discussion of Input Resistance and Impedance

Appendix 2 Propagation in Cardiac Muscle and Smooth Muscles

AII Some Experimental Facts

AIII Electric Field Model

AIV Electronic Model for Simulation of Propagation

AV PSpice Model for Simulation of Propagation

BIBLIOGRAPHY

Chapter 19. Electrogenesis of Membrane Excitability

I Summary

II Introduction

III Action Potential Characteristics

IV Electrogenesis of Action Potentials

V Effect of Resting Potential on Action Potential

VI Electrogenesis of Afterpotentials

Appendix

AII Additional Information on K+ Channels

AIII Whole-Cell Voltage Clamp

BIBLIOGRAPHY

Chapter 20. Patch-Clamp Techniques

I Introduction

II Applications of the Patch-Clamp Technique

III Patch-Clamp Techniques

IV Data Acquisition

V Current Recordings and Analysis

VI Automated Patch-clamp

Acknowledgments

BIBLIOGRAPHY

Chapter 21. Structure and Mechanism of Voltage-Gated Ion Channels

I Summary

II Introduction: How Is Ion Channel Structure Studied?

III Biochemistry of Ion Channels: Purification and Characterization of Voltage-Gated Channels

IV Channel Structure Investigation through Manipulation of DNA Sequences Encoding Channel Polypeptides

V Molecular Mechanisms of Channel Function: How Does One Investigate Them?

VI Isoforms of Voltage-Gated Channels as Part of a Large Superfamily

VII Future Directions

BIBLIOGRAPHY

Chapter 22. Biology of Gap Junctions

I Introduction

II Advantages of Electrical Synapses in Excitable Cells

III Ubiquitous Membrane Permeable Junctions

IV Structural Candidates for the Permeable Cell Junction

V Ultrastructural Characterization of Gap Junctions and Correlations with Cell Coupling

VI Molecular and Structural Studies of Gap Junction Proteins

VII Two Large Families of Gap Junction Proteins

VIII Channels within Gap Junctions

IX Evidence for Charge Selectivity

X Channel Properties of Different Connexins

XI Gating by Ions and Second Messengers

XII Regulation of Functions of Connexin-Based Gap Junctions at Multiple Levels

XIII Specific Biological Functions of Gap Junctions

XIV Gap Junctions in Human Disease and in Murine Models of Human Disease

In Memoriam

BIBLIOGRAPHY

Chapter 23. Regulation of Cardiac Ion Channels by Cyclic Nucleotide-Dependent Phosphorylation

I Summary

II Introduction

III Regulation of the Cardiac L-type Ca2+ Channels by Cyclic AMP

IV Regulation of the L-type Ca2+ Channels by Cyclic GMP

V Phosphodiesterases

VI Compartmentalization of Cyclic Nucleotides

BIBLIOGRAPHY

Chapter 24. Direct Regulation of Ion Channels by GTP-Binding Proteins

I Introduction

II G-Protein-Coupled Receptors

III The G-Protein Cyclic Reaction Mediates Receptor-to-Channel Signal Transmission

IV Electrophysiological Evidence for K+ Channel Activation by G Proteins

V Electrophysiological Properties of KG Channels

VI Direct Coupling of KG Channel Subunits to Gβγ

VII Structural Basis of the Regulation of KG Channel Activity

VIII RGS Proteins Confer Voltage-Dependent Gating on KG Channel

IX Conclusions

BIBLIOGRAPHY

Chapter 25. Developmental Changes in Ion Channels

I Summary

II Introduction

III Cardiomyocytes

IV Skeletal Muscle Fibers

V Neurons

VI Concluding Remarks

BIBLIOGRAPHY

Chapter 26. Regulation of Ion Channel Localization and Activity Through Interactions with the Cytoskeleton

I Summary

II General Introduction

III Mechanisms for Interactions Between the Cytoskeleton and Ion Channels

IV General Conclusions

BIBLIOGRAPHY

Chapter 27. Why are So Many Ion Channels Mechanosensitive?

I Summary

II Introduction

III Eukaryotic MS Channels – Bilayer Structure, Bilayer Deformation

IV Channel Mechanosensitivity – Tuning of Channel Behavior

V VGCS and the Mechanosensitivity of Discrete Transitions

VI Bilayer Structure in X, Y and Z – One LPP Here, Another LPP There

VII Physiology? Read with Caution. Proceed with Caution

BIBLIOGRAPHY

Section IV Ion Channels as Targets for Toxins, Drugs, and Genetic Diseases

Chapter 28. Ion Channels as Targets for Toxins

I Summary

II Introduction

III Voltage-Gated Sodium Channels (VGSCs; NaV1.x)

IV Voltage-Activated and Ca2+-Activated Potassium Channels

V Voltage-Dependent Calcium Channels

VI Other Toxins and Channels

BIBLIOGRAPHY

Chapter 29. Ion Channels as Targets for Drugs

I Summary

II Calcium Channels

III Sodium (Na+) Channels

BIBLIOGRAPHY

Chapter 30. Inherited Diseases of Ion Transport

I Summary

II Introduction

III Identifying Heritable Mutations Underlying Diseases of Ion Transport

IV Familial Hemiplegic Migraine

V Cystic Fibrosis

VI Long QT Syndrome

VII Myotonia and Periodic Paralysis of Skeletal Muscle

VIII Malignant Hyperthermia

IX Liddle’s Syndrome

X Bartter Syndrome

BIBLIOGRAPHY

Section V Synaptic Transmission and Sensory Transduction

Chapter 31. Ligand-Gated Ion Channels

I Summary

II Introduction

III Classes of Ligand-Gated Ion Channels

IV Basic Physiological Features

V Molecular Structure

VI Neuronal Acetylcholine Receptor Channels

VII γ-Aminobutyric Acid and Glycine Receptor Channels

VIII Glutamate Receptor Channels

BIBLIOGRAPHY

Chapter 32. Synaptic Transmission

I Summary

II Introduction

III Structure and Function of Chemical Synapses: An Overview

IV Neurotransmission

BIBLIOGRAPHY

Chapter 33. Excitation—Secretion Coupling

I Summary

II Introduction

III Cellular Components Involved in Excitation–Secretion Coupling

IV Cellular and Molecular Events in Chromaffin, Mast Cells and Neuronal Synaptic Vesicles

V Hormone Release in Endocrine Cells

Acknowledgments

BIBLIOGRAPHY

Chapter 34. Stimulus—Response Coupling in Metabolic Sensor Cells

I Introduction

II Stimulus–Secretion Coupling in the Pancreatic Islet Cells

III Metabolic Sensing as Protection from Hypometabolic Injury

IV Stimulus–Secretion Coupling in Carotid Chemoreceptor Cells

V Stimulus–Contraction Coupling in Vascular Smooth Muscle Cells

VI Coupling of Oxygen Sensing to Red Cell Production by Erythropoietin-Secreting Cells

Acknowledgments

BIBLIOGRAPHY

Chapter 35. Cyclic Nucleotide-Gated Ion Channels

I Summary

II Introduction

III Physiological Roles and Locations

IV Control by Cyclic Nucleotide Enzyme Cascades

V Functional Properties

VI Molecular Structure

VII Functional Modulation

BIBLIOGRAPHY

Chapter 36. Sensory Receptors and Mechanotransduction

I Introduction

II Sensory Transduction

III Sensory Adaptation

IV Information Transmission by Sensory Receptors

V Mechanoreceptors

VI Experimental Mechanoreceptor Preparations

VII Steps in Mechanoreception

VIII Efferent Control of Mechanoreceptors

IX Conclusions

BIBLIOGRAPHY

Chapter 37. Acoustic Transduction

I Summary

II Introduction

III Mammalian Inner Ear Structure

IV Cell Physiology of Endolymph Homeostasis

V Genetic Basis of Deafness

VI Cell Physiology of Acoustic Transduction

VII Concluding Remarks

Acknowledgment

BIBLIOGRAPHY

Chapter 38. Visual Transduction

I Summary

II Introduction

III Photoreceptor Cells

IV Physiology of Visual Transduction

V Molecular Mechanisms

BIBLIOGRAPHY

Chapter 39. Gustatory and Olfactory Sensory Transduction

I Summary

II Introduction

III Taste Receptor Cells

IV Olfactory Receptor Cells

BIBLIOGRAPHY

Chapter 40. Infrared Sensory Organs

I Summary

II Introduction

III Nature of the Stimulus: What is Infrared (IR) Radiation?

IV Infrared-Sensitive Pit Organs in Snakes

BIBLIOGRAPHY

Chapter 41. Electroreceptors and Magnetoreceptors

I Summary

II Introduction

III Ampullary Electroreceptors

IV Tuberous Electroreceptors

BIBLIOGRAPHY

Section VI Muscle and Other Contractile Systems

Chapter 42. Skeletal Muscle Excitability

I Summary

II Introduction

III General Overview of Electrogenesis of the Action Potential

IV Ion Channel Activation and Inactivation

V Slow Delayed Rectifier K+ Current

VI Mechanisms of Repolarization

VII ATP-Dependent K+ Channels

VIII Electrogenesis of Depolarizing Afterpotentials

IX Ca2+-Dependent Slow Action Potentials

X Developmental Changes in Membrane Properties

XI Electrogenic Na+-K+ Pump Stimulation

XII Slow Fibers

XIII Conduction of the Action Potential

XIV Excitation Delivery to Fiber Interior by Conduction into the T-Tubular System

Appendix

AII More Information on KATP Channels

AIII Further Evidence that the T-Tubules Fire Na+-Dependent APS

AIV Propagation Velocity in a Passive Cable

AV Evidence for T-Tubule Communication with the SR across the Triadic Junction under Some Conditions

AVI Invertebrate Striated Muscle Fibers

BIBLIOGRAPHY

Chapter 43. Cardiac Action Potentials

I Summary

II Introduction

III Resting Membrane Potential

IV Currents During the Action Potential Phases

V Additional Currents Contributing to the Action Potential

VI Regional Differences in Action Potentials

VII Automaticity

VIII Channelopathies

BIBLIOGRAPHY

Chapter 44. Smooth Muscle Excitability

I Introduction

II Determination of Resting Membrane Potential in SMCS

III Potassium Channels

IV Voltage-Dependent Calcium Channels

V Transient Receptor Potential (TRP) Channels

VI Excitation of Gastrointestinal SMCS

VII Airway Smooth Muscle

VIII Concluding Remarks

Acknowledgments

BIBLIOGRAPHY

Chapter 45. Excitation—Contraction Coupling in Skeletal Muscle

I Summary

II Introduction

III Overview of EC Coupling

IV Speed of Skeletal Muscle Activation

V Membrane Architecture of EC Coupling

VI The DHPR Protein

VII The Ryanodine Receptor

VIII Physiological Interactions Between the DHPR and RyR1

Acknowledgment

BIBLIOGRAPHY

Chapter 46. Contraction of Muscles

I Summary

II Introduction

III The Mechanisms of Force Production and Shortening: Muscle Mechanics

IV Muscle Energetics

V Muscle Metabolism

VI Comparative Mechanochemical Function

BIBLIOGRAPHY

Chapter 47. Flagella, Cilia, Actin- and Centrin-based Movement

I Introduction

II Bacterial flagella

III Cilia

IV Non-Muscle Actin

V Biological Springs

VI Cannons

VII A Few Lessons Learned

BIBLIOGRAPHY

Chapter 48. Electrocytes of Electric Fish

I Summary

II Introduction

III Anatomy of Electrophorus and Mechanism of the Electrical Discharge

IV Electrocyte Membrane Electrophysiology

V Comparative Physiology of Electrophorus and Torpedo – Models for Mammalian Excitable Cells

BIBLIOGRAPHY

Section VII Protozoa and Bacteria

Chapter 49. Physiological Adaptations of Protists

I Introduction: Terminology and Phylogeny

II Biophysical Constraints of Scale: the Example of Filter-Feeding

III Nutrition and Excretion

IV Energetic Adaptations: Mitochondria and their Relatives

V Sensory Adaptations, Membrane Potentials and Ion Channels

VI Incorporation of Physiological Units from Other Cells

VII Structures with Unknown Functions

VIII Coordinated Protistan Responses to Gravity and to Gradients of Oxygen and Light: an Example from Physiological Ecology

IX Summary: Protistan Diversity

Acknowledgments

BIBLIOGRAPHY

Chapter 50. Physiology of Prokaryotic Cells

I The Diversity of Prokaryotic Organisms

II Prokaryotic Cytology

III Energetics of Bacterial Cells

IV Solute Transport

V Metabolic Strategies

VI Responding to the Environment

VII The Physiology of Pathogenesis

VIII Prokaryotes Living in Extreme Environments

IX Conclusions

BIBLIOGRAPHY

Section VIII Specialized Processes: Photosynthesis and Bioluminescence

Chapter 51. Photosynthesis

I Summary

II Introduction

III Chloroplasts

IV Biochemistry of Carbon Assimilation

V Formation of ATP

VI Photosynthetic Electron Transport

VII Regulation of Photosynthesis

BIBLIOGRAPHY

Chapter 52. Bioluminescence

I Summary

II Introduction

III What is Bioluminescence? Physical and Chemical Mechanisms

IV Luminous Organisms: Abundance, Diversity and Distribution

V Functions of Bioluminescence

VI Bacterial Luminescence

VII Dinoflagellate Luminescence

VIII Coelenterates and Ctenophores

IX Firefly Luminescence

X Other Organisms: Other Chemistries

XI Applications of Bioluminescence

XII Concluding Remarks

BIBLIOGRAPHY

Appendix: Excitability of Smooth Muscles: Some Basic Facts

I Fast Na+ Channels in Smooth Muscle Cells

II Propagation of Overshooting Action Potentials in Intestinal Smooth Muscle

III Vascular Smooth Muscle: Part 1

IV Vascular Smooth Muscle: Part 2

V High Input Resistance and Short Length Constant

VI Induction of APs by Ba2+ and TEA+

VII Enhancement of the TEA-Induced APS

VIII Excitatory Junction Potentials Sometimes Give Rise to APS: Analogy with Slow Fibers of Skeletal Muscle

IX Electrical Equivalent Circuit for VSM Cells

Index

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DNA and Biotechnology 3rd Edition

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Dna And Biotechnology 3Rd Edition Pdf

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DNA and Biotechnology 3rd Edition PDF is Appropriate for a wide range of disciplines, from biology to non-biology, law and nursing majors, DNA and Biotechnology uses a straightforward and comprehensive writing style that gives the educated layperson a survey of DNA by presenting a brief history of genetics, a clear outline of techniques that are in use, and highlights of breakthroughs in hot topic scientific discoveries.

  • Engaging and straightforward scientific writing style
  • Comprehensive forensics chapter
  • Parallel Pedagogic material designed to help both readers and teachers
  • Highlights in the latest scientific discoveries
  • Outstanding full-color illustration that walk reader through complex concepts
Table of Contents

1. The roots of DNA Research
2. The Double Helix
3. DNA in Action
4. Tools of the DNA Trade
5. Working with DNA
6. Human Genomics
7. Bioinformatics
8. DNA in Froensics
9. Exploring Cell Fate
10. Genetic Diseases
11. Gene Therapy
12. Stem Cell Research
13. Pharmaceutical Biotechnology
14. Animal Biotechnology
15. Agricultural Biotechnology
16. Genes and Race

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DNA'Protein Interactions: Principles and Protocols 2nd Edition PDF

DNA’Protein Interactions: Principles and Protocols 2nd Edition

Dna'protein Interactions: Principles And Protocols 2Nd Edition Pdf

By Tom Moss

Table of Contents

Preface

Contributors

1 Filter-Binding Assays
Peter G. Stockley

2 Electrophoretic Mobility Shift Assays for the Analysis
of DNA–Protein Interactions
Marc-André Laniel, Alain Béliveau, and Sylvain L. Guérin

3 DNase I Footprinting
Benoît Leblanc and Tom Moss

4 Footprinting with Exonuclease III
Willi Metzger and Hermann Heumann.

5 Hydroxyl Radical Footprinting
Evgeny Zaychikov, Peter Schickor, Ludmilla Denissova,
and Hermann Heumann

6 The Use of Diethyl Pyrocarbonate and Potassium
Permanganate as Probes for Strand Separation and Structural
Distortions in DNA
Brenda F. Kahl and Marvin R. Paule

7 Footprinting DNA–Protein Interactions in Native Polyacrylamide Gels
by Chemical Nucleolytic Activity of 1,10-Phenanthroline-Copper
Athanasios G. Papavassiliou

8 Uranyl Photofootprinting
Peter E. Nielsen

9 Osmium Tetroxide Modification and the Study
of DNA–Protein Interactions
James A. McClellan

10 Determination of a Transcription-Factor-Binding Site by Nuclease
Protection Footprinting onto Southwestern Blots
Athanasios G. Papavassiliou

11 Diffusible Singlet Oxygen as a Probe of DNA Deformation
Malcolm Buckle and Andrew A. Travers

12 Ultraviolet-Laser Footprinting
Johannes Geiselmann and Frederic Boccard

13 In Vivo DNA Analysis
Régen Drouin, Jean-Philippe Therrien, Martin Angers,
and Stéphane Ouellet

14 Identification of Protein–DNA Contacts with Dimethyl Sulfate:
Methylation Protection and Methylation Interference
Peter E. Shaw and A. Francis Stewart

15 Ethylation Interference
Iain W. Manfield and Peter G. Stockley

16 Hydroxyl Radical Interference
Peter Schickor, Evgeny Zaychikov, and Hermann Heumann

17 Identification of Sequence-Specific DNA-Binding Proteins
by Southwestern Blotting
Simon Labbé, Gale Stewart, Olivier LaRochelle,
Guy G. Poirier, and Carl Séguin

18 A Competition Assay for DNA Binding Using the Fluorescent
Probe ANS
Ian A. Taylor and G. Geoff Kneale

19 Site-Directed Cleavage of DNA by Linker Histone Protein-Fe(II)
EDTA Conjugates
David R. Chafin and Jeffrey J. Hayes

20 Nitration of Tyrosine Residues in Protein–Nucleic Acid Complexes
Simon E. Plyte

21 Chemical Modification of Lysine by Reductive Methylation:
A Probe of Residues Involved in DNA Binding
Ian A. Taylor and Michelle Webb

22 Limited Proteolysis of Protein–Nucleic Acid Complexes
Simon E. Plyte and G. Geoff Kneale

23 Ultraviolet Crosslinking of DNA–Protein Complexes
via 8-Azidoadenine
Rainer Meffert, Klaus Dose, Gabriele Rathgeber,
and Hans-Jochen Schäfer

24 Site-Specific Protein–DNA Photocrosslinking: Analysis of Bacterial
Transcription Initiation Complexes
Nikolai Naryshkin, Younggyu Kim, Qianping Dong,
and Richard H. Ebright

25 Site-Directed DNA Photoaffinity Labeling of RNA Polymerase III
Transcription Complexes
Jim Persinger and Blaine Bartholomew

26 Use of Site-Specific Protein–DNA Photocrosslinking to Analyze
the Molecular Organization of the RNA Polymerase
II Initiation Complex
François Robert and Benoît Coulombe

27 UV Laser-Induced Protein–DNA Crosslinking
Stefan I. Dimitrov and Tom Moss

28 Plasmid Vectors for the Analysis of Protein-Induced
DNA Bending
Christian Zwieb and Sankar Adhya

29 Engineering Nucleic Acid-Binding Proteins by Phage Display
Mark Isalan and Yen Choo

30 Genetic Analysis of DNA–Protein Interactions Using a Reporter
Gene Assay in Yeast
David R. Setzer, Deborah B. Schulman,
and Michael J. Bumbulis
31 Assays for Transcription Factor Activity

Virgil Rhodius, Nigel Savery, Annie Kolb,
and Stephen Busby

32 Assay of Restriction Endonucleases Using Oligonucleotides
Bernard A. Connolly, Hsiao-Hui Liu, Damian Parry,
Lisa E. Engler, Michael R. Kurpiewski,
and Linda Jen-Jacobson

33 Analysis of DNA–Protein Interactions by Intrinsic Fluorescence
Mark L. Carpenter, Anthony W. Oliver, and G. Geoff Kneale

34 Circular Dichroism for the Analysis of Protein–DNA Interactions
Mark L. Carpenter, Anthony W. Oliver, and G. Geoff Kneale

35 Calorimetry of Protein–DNA Complexes and Their Components
Christopher M. Read and Ilian Jelesarov

36 Surface Plasmon Resonance Applied to DNA–Protein Complexes
Malcolm Buckle

37 Reconstitution of Protein–DNA Complexes for Crystallization
Rachel M. Conlin and Raymond S. Brown

38 Two-Dimensional Crystallization of Soluble Protein Complexes
Patrick Schultz, Nicolas Bischler, and Luc Lebeau

39 Atomic Force Microscopy of DNA and Protein–DNA Complexes
Using Functionalized Mica Substrates
Yuri L. Lyubchenko, Alexander A. Gall,
and Luda S. Shlyakhtenko

40 Electron Microscopy of Protein–Nucleic Acid Complexes: Uniform
Spreading of Flexible Complexes, Staining with a Uniform Thin
Layer of Uranyl Acetate, and Determining Helix Handedness
Carla W. Gray

41 Scanning Transmission Electon Microscopy
of DNA–Protein Complexes
Joseph S. Wall and Martha N. Simon

42 Determination of Nuleic Acid Recognition Sequences by SELEX
Philippe Bouvet

43 High DNA–Protein Crosslinking Yield with Two-Wavelength
Femtosecond Laser Irradiation
Christoph Russmann, Rene Beigang, and Miguel Beato
Appendices:
Appendix I: EMSA/Gel Shift Conditions
Appendix II: DNA-Modification/Cleavage Reagents
Index

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Dynamic Systems Biology Modeling and Simulation

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Dynamic Systems Biology Modeling and Simulation

Dynamic Systems Biology Modeling And Simulation Pdf

By Joseph Distefano

Dynamic Systems Biology Modeling and Simulation PDF consolidates and unifies classical and contemporary multiscale methodologies for mathematical modeling and computer simulation of dynamic biological systems – from molecular/cellular, organ-system, on up to population levels. The book pedagogy is developed as a well-annotated, systematic tutorial – with clearly spelled-out and unified nomenclature – derived from the author’s own modeling efforts, publications and teaching over half a century. Ambiguities in some concepts and tools are clarified and others are rendered more accessible and practical. The latter include novel qualitative theory and methodologies for recognizing dynamical signatures in data using structural (multicompartmental and network) models and graph theory; and analyzing structural and measurement (data) models for quantification feasibility. The level is basic-to-intermediate, with much emphasis on biomodeling from real biodata, for use in real applications.

  • Introductory coverage of core mathematical concepts such as linear and nonlinear differential and difference equations, Laplace transforms, linear algebra, probability, statistics and stochastics topics
  • The pertinent biology, biochemistry, biophysics or pharmacology for modeling are provided, to support understanding the amalgam of “math modeling” with life sciences
  • Strong emphasis on quantifying as well as building and analyzing biomodels: includes methodology and computational tools for parameter identifiability and sensitivity analysis; parameter estimation from real data; model distinguishability and simplification; and practical bioexperiment design and optimization
  • Companion website provides solutions and program code for examples and exercises using Matlab, Simulink, VisSim, SimBiology, SAAMII, AMIGO, Copasi and SBML-coded models
  • A full set of PowerPoint slides are available from the author for teaching from his textbook. He uses them to teach a 10 week quarter upper division course at UCLA, which meets twice a week, so there are 20 lectures. They can easily be augmented or stretched for a 15 week semester course
  • Importantly, the slides are editable, so they can be readily adapted to a lecturer’s personal style and course content needs. The lectures are based on excerpts from 12 of the first 13 chapters of DSBMS. They are designed to highlight the key course material, as a study guide and structure for students following the full text content
Table of Contents
  • Quotes
  • Preface to the First Edition
    • Pedagogical Struggles
    • Crystallizing and Focusing – My Way
    • How to Use this Book in the Classroom
    • Acknowledgements
    • References
  • Chapter 1. Biosystem Modeling & Simulation: Nomenclature & Philosophy
    • Overview
    • Modeling Definitions
    • Modeling Essential System Features
    • Primary Focus: Dynamic (Dynamical) System Models
    • Measurement Models & Dynamic System Models Combined: Important!
    • Stability
    • Top-Down & Bottom-Up Modeling
    • Source & Sink Submodels: One Paradigm for Biomodeling with Subsystem Components
    • Systems, Integration, Computation & Scale in Biology
    • Overview of the Modeling Process & Biomodeling Goals
    • Looking Ahead: A Top-Down Model of the Chapters
    • References
  • Chapter 2. Math Models of Systems: Biomodeling 101
    • Some Basics & a Little Philosophy
    • Algebraic or Differential Equation Models
    • Differential & Difference Equation Models
    • Different Kinds of Differential & Difference Equation Models
    • Linear & Nonlinear Mathematical Models
    • Piecewise-Linearized Models: Mild/Soft Nonlinearities
    • Solution of Ordinary Differential (ODE) & Difference Equation (DE) Models
    • Special Input Forcing Functions (Signals) & Their Model Responses: Steps & Impulses
    • State Variable Models of Continuous-Time Systems
    • Linear Time-Invariant (TI) Discrete-Time Difference Equations (DEs) & Their Solution
    • Linearity & Superposition
    • Laplace Transform Solution of ODEs
    • Transfer Functions of Linear TI ODE Models
    • More on System Stability
    • Looking Ahead
    • Exercises
    • References
  • Chapter 3. Computer Simulation Methods
    • Overview
    • Initial-Value Problems
    • Graphical Programming of ODEs
    • Time-Delay Simulations
    • Multiscale Simulation and Time-Delays
    • Normalization of ODEs: Magnitude- & Time-Scaling
    • Numerical Integration Algorithms: Overview
    • The Taylor Series
    • Taylor Series Algorithms for Solving Ordinary Differential Equations
    • Computational/Numerical Stability
    • Self-Starting ODE Solution Methods
    • Algorithms for Estimating and Controlling Stepwise Precision
    • Taylor Series-Based Method Comparisons
    • Stiff ODE Problems
    • How to Choose a Solver?
    • Solving Difference Equations (DEs) Using an ODE Solver
    • Other Simulation Languages & Software Packages
    • Two Population Interaction Dynamics Simulation Model Examples
    • Taking Stock & Looking Ahead
    • Exercises
    • References
  • Chapter 4. Structural Biomodeling from Theory & Data: Compartmentalizations
    • Introduction
    • Compartmentalization: A First-Level Formalism for Structural Biomodeling
    • Mathematics of Multicompartmental Modeling from the Biophysics
    • Nonlinear Multicompartmental Biomodels: Special Properties & Solutions
    • Dynamic System Nonlinear Epidemiological Models
    • Compartment Sizes, Concentrations & the Concept of Equivalent Distribution Volumes
    • General n-Compartment Models with Multiple Inputs & Outputs
    • Data-Driven Modeling of Indirect & Time-Delayed Inputs
    • Pools & Pool Models: Accommodating Inhomogeneities
    • Recap & Looking Ahead
    • Exercises
    • References
  • Chapter 5. Structural Biomodeling from Theory & Data: Sizing, Distinguishing & Simplifying Multicompartmental Models
    • Introduction
    • Output Data (Dynamical Signatures) Reveal Dynamical Structure
    • Multicompartmental Model Dimensionality, Modal Analysis & Dynamical Signatures
    • Model Simplification: Hidden Modes & Additional Insights
    • Biomodel Structure Ambiguities: Model Discrimination, Distinguishability & Input–Output Equivalence
    • *Algebra and Geometry of MC Model Distinguishability
    • Reducible, Cyclic & Other MC Model Properties
    • Tracers, Tracees & Linearizing Perturbation Experiments
    • Recap and Looking Ahead
    • Exercises
    • References
  • Chapter 6. Nonlinear Mass Action & Biochemical Kinetic Interaction Modeling
    • Overview
    • Kinetic Interaction Models
    • Law of Mass Action
    • Reaction Dynamics in Open Biosystems
    • Enzymes & Enzyme Kinetics
    • Enzymes & Introduction to Metabolic and Cellular Regulation
    • Exercises
    • Extensions: Quasi-Steady State Assumption Theory
    • References
  • Chapter 7. Cellular Systems Biology Modeling: Deterministic & Stochastic
    • Overview
    • Enzyme-Kinetics Submodels Extrapolated to Other Biomolecular Systems
    • Coupled-Enzymatic Reactions & Protein Interaction Network (PIN) Models
    • Production, Elimination & Regulation Combined: Modeling Source, Sink & Control Components
    • The Stoichiometric Matrix N
    • Special Purpose Modeling Packages in Biochemistry, Cell Biology & Related Fields
    • Stochastic Dynamic Molecular Biosystem Modeling
    • When a Stochastic Model is Preferred
    • Stochastic Process Models & the Gillespie Algorithm
    • Exercises
    • References
  • Chapter 8. Physiologically Based, Whole-Organism Kinetics & Noncompartmental Modeling
    • Overview
    • Physiologically Based (PB) Modeling
    • Experiment Design Issues in Kinetic Analysis (Caveats)
    • Whole-Organism Parameters: Kinetic Indices of Overall Production, Distribution & Elimination
    • Noncompartmental (NC) Biomodeling & Analysis (NCA)
    • Recap & Looking Ahead
    • Exercises
    • References
  • Chapter 9. Biosystem Stability & Oscillations
    • Overview/Introduction
    • Stability of NL Biosystem Models
    • Stability of Linear System Models
    • Local Nonlinear Stability via Linearization
    • Bifurcation Analysis
    • Oscillations in Biology
    • Other Complex Dynamical Behaviors
    • Nonlinear Modes
    • Recap & Looking Ahead
    • Exercises
    • References
  • Chapter 10. Structural Identifiability
    • Introduction
    • Basic Concepts
    • Formal Definitions: Constrained Structures, Structural Identifiability & Identifiable Combinations
    • Unidentifiable Models
    • SI Under Constraints: Interval Identifiability with Some Parameters Known
    • SI Analysis of Nonlinear (NL) Biomodels
    • What’s Next?
    • Exercises
    • References
  • Chapter 11. Parameter Sensitivity Methods
    • Introduction
    • Sensitivity to Parameter Variations: The Basics
    • State Variable Sensitivities to Parameter Variations
    • Output Sensitivities to Parameter Variations
    • *Output Parameter Sensitivity Matrix & Structural Identifiability
    • *Global Parameter Sensitivities
    • Recap & Looking Ahead
    • Exercises
    • References
  • Chapter 12. Parameter Estimation & Numerical Identifiability
    • Biomodel Parameter Estimation (Identification)
    • Residual Errors & Parameter Optimization Criteria
    • Parameter Optimization Methods 101: Analytical and Numerical
    • Parameter Estimation Quality Assessments
    • Other Biomodel Quality Assessments
    • Recap and Looking Ahead
    • Exercises
    • References
  • Chapter 13. Parameter Estimation Methods II: Facilitating, Simplifying & Working With Data
    • Overview
    • Prospective Simulation Approach to Model Reliability Measures
    • Constraint-Simplified Model Quantification
    • Model Reparameterization & Quantifying the Identifiable Parameter Combinations
    • The Forcing-Function Method
    • Multiexponential (ME) Models & Use as Forcing Functions
    • Model Fitting & Refitting With Real Data
    • Recap and Looking Ahead
    • Exercises
    • References
  • Chapter 14. Biocontrol System Modeling, Simulation, and Analysis
    • Overview
    • Physiological Control System Modeling
    • Neuroendocrine Physiological System Models
    • Structural Modeling & Analysis of Biochemical & Cellular Control Systems
    • Transient and Steady-State Biomolecular Network Modeling
    • Metabolic Control Analysis (MCA)
    • Recap and Looking Ahead
    • Exercises
    • References
  • Chapter 15. Data-Driven Modeling and Alternative Hypothesis Testing
    • Overview
    • Statistical Criteria for Discriminating Among Alternative Models
    • Macroscale and Mesoscale Models for Elucidating Biomechanisms
    • Mesoscale Mechanistic Models of Biochemical/Cellular Control Systems
    • Candidate Models for p53 Regulation
    • Recap and Looking Ahead
    • Exercises
    • References
  • Chapter 16. Experiment Design and Optimization
    • Overview
    • A Formal Model for Experiment Design
    • Input–Output Experiment Design from the TF Matrix
    • Graphs and Cutset Analysis for Experiment Design
    • Algorithms for Optimal Experiment Design
    • Sequential Optimal Experiment Design
    • Recap and Looking Ahead
    • Exercises
    • References
  • Chapter 17. Model Reduction and Network Inference in Dynamic Systems Biology
    • Overview
    • Local and Global Parameter Sensitivities
    • Model Reduction Methodology
    • Parameter Ranking
    • Added Benefits: State Variables to Measure and Parameters to Estimate
    • Global Sensitivity Analysis (GSA) Algorithms
    • What’s Next?
    • Exercises
    • References
  • Appendix A. A Short Course in Laplace Transform Representations & ODE Solutions
    • Transform Methods
    • Laplace Transform Representations and Solutions
    • Key Properties of the Laplace Transform (LT) & its Inverse (ILT)
    • Short Table of Laplace Transform Pairs
    • Laplace Transform Solution of Ordinary Differential Equations (ODEs)
  • Appendix B. Linear Algebra for Biosystem Modeling
    • Overview
    • Matrices
    • Vector Spaces (V.S.)
    • Linear Equation Solutions
    • Measures & Orthogonality
    • Matrix Analysis
    • Matrix Differential Equations
    • Singular Value Decomposition (SVD) & Principal Component Analysis (PCA)
  • Appendix C. Input–Output & State Variable Biosystem Modeling: Going Deeper
    • Inputs & Outputs
    • Dynamic Systems, Models & Causality
    • Input–Output (Black-Box) Models
    • Time-Invariance (TI)
    • Continuous Linear System Input–Output Models
    • Structured State Variable Models
    • Discrete-Time Dynamic System Models
    • Composite Input–Output and State Variable Models
    • State Transition Matrix for Linear Dynamic Systems
    • The Adjoint Dynamic System
    • Equivalent Dynamic Systems: Different Realizations of State Variable Models – Nonuniqueness Exposed
    • Illustrative Example: A 3-Compartment Dynamic System Model & Several Discretized Versions of It
    • Transforming Input–Output Data Models into State Variable Models: Generalized Model Building
  • Appendix D. Controllability, Observability & Reachability
    • Basic Concepts and Definitions
    • Observability and Controllability of Linear State Variable Models
    • Linear Time-Varying Models
    • Linear Time-Invariant Models
    • Output Controllability
    • Output Function Controllability
    • Reachability
    • Constructibility
    • Controllability and Observability with Constraints
    • Positive Controllability
    • Relative Controllability (Reachability)
    • Conditional Controllability
    • Structural Controllability and Observability
    • Observability and Identifiability Relationships
    • Controllability and Observability of Stochastic Models
  • Appendix E. Decomposition, Equivalence, Minimal & Canonical State Variable Models
    • Realizations (Modeling Paradigms)
    • The Canonical Decomposition Theorem
    • How to Decompose a Model
    • Controllability and Observability Tests Using Equivalent Models
    • Observable and Controllable Canonical Forms from Arbitrary State Variable Models Using Equivalence Properties
  • Appendix F. More on Simulation Algorithms & Model Information Criteria
    • Additional Predictor-Corrector Algorithms
    • Derivation of the Akaike Information Criterion (AIC)
    • The Stochastic Fisher Information Matrix (FIM): Definitions & Derivations
  • Index

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Dynamics of Large Herbivore Populations in Changing Environments

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Dynamics of Large Herbivore Populations in Changing Environments PDF

Dynamics of Large Herbivore Populations in Changing Environments

Dynamics Of Large Herbivore Populations In Changing Environments Pdf

By Norman Owen-Smith

Dynamics of Large Herbivore Populations in Changing Environments PDF aims to reconcile theoretical models of population dynamics with what is currently known about the population dynamics of large mammalian herbivores. It arose from a working group established at the National Center for Ecological Analysis and Synthesis at the University of California, Santa Barbara, to address the need for models that better accommodate environmental variability, especially for herbivores dependent on changing vegetation resources. The initial chapter reviews findings from definitive long-term studies of certain other ungulate populations, many based on individually identifiable animals. Other chapters cover climatic influences, emphasising temperate versus tropical contrasts, and demographic processes underlying population dynamics, more generally. There are new assessments of irruptive population dynamics, and of the consequences of landscape heterogeneity for herbivore populations. An initial review of candidate population models is followed up by a final chapter outlining how these models might be modified to better accommodate environmental variability. The contents provide a foundation for resolving problems of diminishing large mammal populations in Africa, over-abundant ungulate populations elsewhere, and general consequences of global change for biodiversity conservation. This book will serve as a definitive outline of what is currently known about the population dynamics of large herbivores.

Table of Contents

Contributors

Preface

1 Definitive case studies

Norman Owen-Smith and Jason P. Marshal

1.1 Red deer on Rum

1.2 Soay sheep on Hirta

1.3 Roe deer in France

1.4 Bighorn sheep in Alberta

1.5 Kudu in Kruger

1.6 Wildebeest in Serengeti

1.7 Moose on Isle Royale

1.8 Elk in North Yellowstone

1.9 Overview

Acknowledgments

References

2 The suite of population models

Norman Owen-Smith

2.1 Models of density dependence

2.2 Autoregressive time-series models

2.3 Age- or stage-structured models

2.4 Trophic interaction models

2.5 Physiological or metaphysiological models

2.6 Models accommodating spatial structure

2.7 Individual-based models

2.8 Overview

Acknowledgments

References

3 Climatic influences: temperate–tropical contrasts

Norman Owen-Smith

3.1 Temperate environments

3.2 Tropical and subtropical environments

3.3 Effects of predation and hunting

3.4 Overall assessment

Acknowledgments

References

4 Demographic processes: lessons from long-term, individual-based studies

Jean-Michel Gaillard, Tim Coulson and Marco Festa-Bianchet

4.1 Life history of large herbivores: a brief review

4.2 Differential contributions of demographic parameters to population growth

4.3 Climatic variation, density-dependence,andindividual variability

4.4 Conclusions:howcanfutureanalysesof largeherbivoredemography deal with complex demographic processes?

Acknowledgments

References

5 Irruptive dynamics and vegetation interactions

John E. Gross, Iain J. Gordon and Norman Owen-Smith

5.1 Models of herbivore–vegetation interactions

5.2 Examples of irruptive dynamics

5.3 Effects of irruptions on vegetation

5.4 Changing perspectives

5.5 Synthesis

5.6 Implications for conservation and management

Acknowledgments

References

6 How does landscape heterogeneity shape dynamics of large herbivore populations?

N. Thompson Hobbs and Iain J. Gordon

6.1 What is spatial heterogeneity?

6.2 How does spatial heterogeneity influence ungulate population dynamics?

6.3 Mechanisms explaining the influence of spatial heterogeneity on population dynamics

6.4 Influences from high-quality resources

6.5 Influences from buffer resources

6.6 Global change and access to heterogeneity by large herbivores

6.7 Conclusions: the importance of spatial context for population dynamics

Acknowledgments

References

7 Towards an ecology of population dynamics

Norman Owen-Smith

7.1 Phenomenological descriptors

7.2 Time series elaborations

7.3 Environmental structure

7.4 Population structure

7.5 Adaptive responses and environmental contexts

7.6 Summary and conclusions

Acknowledgments

References

Index

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Bioprocess Engineering: Kinetics, Sustainability, and Reactor Design 2nd Edition

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Bioprocess Engineering: Kinetics, Sustainability, and Reactor Design 2nd Edition

Bioprocess Engineering: Kinetics, Sustainability, And Reactor Design 2Nd Edition Pdf

By Shijie Liu

Bioprocess Engineering: Kinetics, Sustainability, and Reactor Design 2nd Edition PDF provides a comprehensive resource on bioprocess kinetics, bioprocess systems, sustainability, and reaction engineering. Author Dr. Shijie Liu reviews the relevant fundamentals of chemical kinetics, batch and continuous reactors, biochemistry, microbiology, molecular biology, reaction engineering, and bioprocess systems engineering, also introducing key principles that enable bioprocess engineers to engage in analysis, optimization, and design with consistent control over biological and chemical transformations. The quantitative treatment of bioprocesses is the central theme in this book, with more advanced techniques and applications being covered in depth. This updated edition reflects advances that are transforming the field, ranging from genetic sequencing, to new techniques for producing proteins from recombinant DNA, and from green chemistry, to process stability and sustainability. The book introduces techniques with broad applications, including the conversion of renewable biomass, the production of chemicals, materials, pharmaceuticals, biologics, and commodities, medical applications, such as tissue engineering and gene therapy, and solving critical environmental problems.

  • Includes the mechanistic description of biotransformations and chemical transformations
  • Provides quantitative descriptions of bioprocesses
  • Contains extensive illustrative drawings, which make the understanding of the subject easy
  • Includes bioprocess kinetics and reactor analysis
  • Contains examples of the various process parameters, their significance, and their specific practical use
  • Incorporates sustainability concepts into the various bioprocesses
Table of Contents

Chapter 1. Introduction

Chapter 2. An Overview of Biological Basics

Chapter 3. An Overview of Chemical Reaction Analysis

Chapter 4. Batch Reactor

Chapter 5. Ideal Flow Reactors

Chapter 6. Kinetic Theory and Reaction Kinetics

Chapter 7 Parametric Estimation

Chapter 8. Enzymes

NEW! Chapter 9. Allosteric Enzymes and Regulations

9.1. Reactions in Life

9.2. Allostericity and cooperativity

9.2.1 Single binding site and saturation binding

9.2.2 Multiple binding sites and Morpheein mechanism

9.3. Enzyme binding and transport

9.4. Kinetics of allosteric enzyme

9.5. Allosteric regulations

9.6. Summary

Recommended Reading Materials

Problems

NEW! Chapter 10. Adsorption

10.1 Introduction

10.2 Thermodynamics of adsorption

10.3 Ideal surface and Langmuir adsorption

10.3.1 Collision theory and adsorption rate

10.3.2 Langmuir adsorption isotherm

10.4 Idealization of non-ideal adsorption and multilayer adsorption

10.4.1 Idealization of non-uniform surface and surface interaction

10.4.2 Multilayer adsorption kinetics

10.4.3 Adsorption isotherm

10.4.4 BET isotherm

10.5 Pore Size and Surface Characterization

10.6. Applications of adsorption

10.7 Summary

Recommended Reading Materials

Problems

Chapter 11. Catalysis and Chemical Reactions on Solid Surfaces

Chapter 12. Cell Growth and Metabolism

Chapter 13. Kinetics of Cell Growth and Batch Cultivation

Chapter 14. Cell Growth and Fermentation

Chapter 15 Ideal Fed-Batch Reactor

Chapter 16. Evolution and Genetic Engineering

Chapter 17. Sustainability: Perspective

Chapter 18 Sustainability and Stability

Chapter 19. Mass Transfer Effects: Immobilized and Heterogeneous Reaction Systems

Chapter 20. Bioreactor Design & Operation

NEW! Chapter 21. Bioprocess Kinetics Experimental Design

21.1 Introduction

21.2 Identification of objectives

21.3 Experimental design

20.4 Model construction

20.5 Summary

Reading Materials

Problems

NEW! Chapter 22. Bioprocess Safety

22.1 Introduction

22.2 Chemicals and materials safety

22.3 Biosafety

22.4 Chemical process hazard

22.5 Bioprocess hazard

22.6 Reactive hazard

22.7 Summary

Reading Materials

Problems

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Biomedical Science Practice Experimental and Professional Skills

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Biomedical Science Practice Experimental and Professional Skills

Biomedical Science Practice Experimental And Professional Skills Pdf

By Hedley Glencross, Nessar Ahmed and Chris Smith and Qiuyu Wang

Biomedical Science Practice Experimental and Professional Skills PDF. Biomedical scientists are the foundation of modern healthcare, from cancer screening to diagnosing HIV, from blood transfusion for surgery to food poisoning and infection control. Without biomedical scientists, the diagnosis of disease, the evaluation of the effectiveness of treatment, and
research into the causes and cures of disease would not be possible.

The Fundamentals of Biomedical Science series is written to reflect the challenges of practicing biomedical science today. It draws together essential basic science with insights into laboratory practice to show how an understanding of the biology of disease is coupled to the analytical approaches
that lead to diagnosis.

Assuming only a minimum of prior knowledge, the series reviews the full range of disciplines to which a Biomedical Scientist may be exposed – from microbiology to cytopathology to transfusion science. Alongside volumes exploring specific biomedical themes and related laboratory diagnosis, an
overarching Biomedical Science Practice volume gives a grounding in the professional and experimental skills with which any Biomedical Scientist must be equipped.

The series
DT Understands the complex roles of Biomedical Scientists in the modern practice of medicine.
DT Understands the development needs of employers and the Profession.
DT Addresses the need for understanding of a range of fundamental sciences in the context of Biomedicine.
DT Places the theoretical aspects of Biomedical Science in their practical context.

Biomedical Science Practice presents the essential practical and professional skills that every biomedical scientist should master, making it the perfect foundation for the study of each of the key subject specialisms that maybe encountered in the biomedical lab.

The book reviews a broad range of professional skills and concepts, including health and safety considerations, personal development, and communication, and also introduces the key experimental and analytical approaches that form the basis of the investigation and diagnosis of clinical conditions.

Drawing on the wealth of experience of a range of biomedical science practitioners and educators, Biomedical Science Practice is the ideal companion throughout your biomedical science education and training.

Table of Contents

Biomedical science and biomedical scientists

Fitness to practice
Communication in laboratory medicine

Health and safety

Statistics and handling data

Preparing and measuring reagents

Samples and sample collection

Microscopy

Electrochemistry

Radioactivity and radiation

Spectroscopy

Centrifugation

Chromatography

Electrophoresis

Immunological techniques

Molecular biology techniques

Laboratory automation

Point of care testing

Quality assurance and management

Personal development

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Biology Today and Tomorrow With Physiology 4th Edition

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Biology Today and Tomorrow With Physiology 4th Edition

Biology Today And Tomorrow With Physiology 4Th Edition Pdf

By Cecie Starr and Christine Evers

Table of Contents

1. Invitation to Biology

2. Molecules of Life

3. Cell Structure

4. Cell Function

5. Capturing and Releasing Energy

6. DNA Structure and Function

7. Gene Expression and Control

8. How Cells Reproduce

9. Observable Patterns of Inheritance

10. Biotechnology

11. Evidence of Evolution

12. Processes of Evolution

13. Early Life and the Microbes

14. Plant Evolution

15. Animal Evolution

16. Population Ecology

17. Ecosystems and Communities

18. The Biosphere

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Biology: The Unity and Diversity of Life 15th Edition

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Biology: The Unity and Diversity of Life 15th Edition

Biology: The Unity And Diversity Of Life 15Th Edition Pdf

By Cecie Starr, Ralph Taggart, Christine Evers and Lisa Starr

Table of Contents

Contents in Brief

Detailed Contents

Preface

Student and Instructor Resources

Acknowledgments

Class Testers and Reviewers

Chapter 1: Invitation to Biology

1.1 Application: Secret Life of Earth

1.2 Life Is More Than the Sum of Its Parts

1.3 How Living Things Are Alike

1.4 How Living Things Differ

1.5 Organizing Information about Species

1.6 The Science of Nature

1.7 Analyzing Experimental Results

1.8 The Nature of Science

Chapter 2: Life’s Chemical Basis

2.1 Mercury Rising

2.2 Building Blocks of Matter

2.3 Why Electrons Matter

2.4 Chemical Bonds

2.5 Hydrogen Bonding and Water

2.6 Acids and Bases

Chapter 3: Molecules of Life

3.1 Fear of Frying

3.2 The Chemistry of Biology

3.3 Carbohydrates

3.4 Lipids

3.5 Proteins

3.6 Nucleic Acids

Chapter 4: Cell Structure

4.1 Food for Thought

4.2 What Is a Cell?

4.3 Introducing the Prokaryotes

4.4 Introducing the Eukaryotic Cell

4.5 The Endomembrane System

4.6 Mitochondria

4.7 Chloroplasts and Other Plastids

4.8 The Cytoskeleton

4.9 Cell Surface Specializations

4.10 The Nature of Life

Chapter 5: Ground Rules of Metabolism

5.1 A Toast to Alcohol Dehydrogenase

5.2 Energy in the World of Life

5.3 Energy in the Molecules of Life

5.4 How Enzymes Work

5.5 Metabolic Pathways

5.6 Cofactors

5.7 A Closer Look at Cell Membranes

5.8 Diffusion across Membranes

5.9 Membrane Transport Mechanisms

5.10 Membrane Trafficking

Chapter 6: Where It Starts-Photosynthesis

6.1 Biofuels

6.2 Overview of Photosynthesis

6.3 Sunlight as an Energy Source

6.4 The Light-Dependent Reactions

6.5 The Light-Independent Reactions

Chapter 7: Releasing Chemical Energy

7.1 Risky Business

7.2 Introduction to Carbohydrate Breakdown Pathways

7.3 Aerobic Respiration Continues

7.4 Aerobic Respiration Ends

7.5 Fermentation

7.6 Alternative Energy Sources in Food

Chapter 8: DNA Structure and Function

8.1 A Hero Dog’s Golden Clones

8.2 Discovery of DNA’s Function

8.3 Discovery of DNA’s Structure

8.4 Eukaryotic Chromosomes

8.5 DNA Replication

8.6 Mutations: Cause and Effect

8.7 Cloning Adult Animals

Chapter 9: From DNA to Protein

9.1 Ricin, RIP

9.2 DNA, RNA, and Gene Expression

9.3 Transcription: DNA to RNA

9.4 RNA and the Genetic Code

9.5 Translation: RNA to Protein

9.6 Consequences of Mutations

Chapter 10: Control of Gene Expression

10.1 Between You and Eternity

10.2 Regulating Gene Expression

10.3 Regulating Gene Expression in Development

10.4 Regulating Gene Expression to Adjust Metabolism

10.5 Epigenetics

Chapter 11: How Cells Reproduce

11.1 Henrietta’s Immortal Cells

11.2 Multiplication by Division

11.3 A Closer Look at Mitosis

11.4 Cytoplasmic Division

11.5 Marking Time with Telomeres

11.6 When Mitosis Is Dangerous

Chapter 12: Meiosis and Sexual Reproduction

12.1 Why Sex?

12.2 Meiosis in Sexual Reproduction

12.3 Visual Tour of Meiosis

12.4 Meiosis Fosters Genetic Diversity

12.5 An Ancestral Connection

Chapter 13: Observing Patterns in Inherited Traits

13.1 Menacing Mucus

13.2 Mendel, Pea Plants, and Inheritance Patterns

13.3 Mendel’s Law of Segregation

13.4 Mendel’s Law of Independent Assortment

13.5 Non-Mendelian Inheritance

13.6 Nature and Nurture

13.7 Complex Variation in Traits

Chapter 14: Chromosomes and Human Inheritance

14.1 Shades of Skin

14.2 Human Chromosomes

14.3 Autosomal Inheritance

14.4 X-Linked Inheritance

14.5 Changes in Chromosome Structure

14.6 Changes in Chromosome Number

14.7 Genetic Screening

Chapter 15: Studying and Manipulating Genomes

15.1 Personal Genetic Testing

15.2 DNA Cloning

15.3 Isolating Genes

15.4 DNA Sequencing

15.5 Genomics

15.6 Genetic Engineering

15.7 Designer Plants

15.8 Biotech Barnyards

15.9 Editing Genomes

Chapter 16: Evidence of Evolution

16.1 Reflections of a Distant Past

16.2 Old Beliefs and New Discoveries

16.3 Evolution by Natural Selection

16.4 Fossils: Evidence of Ancient Life

16.5 Changes in the History of Earth

Chapter 17: Processes of Evolution

17.1 Superbug Farms

17.2 Alleles in Populations

17.3 Genetic Equilibrium

17.4 Patterns of Natural Selection

17.5 Natural Selection and Diversity

17.6 Nonselective Evolution

17.7 Reproductive Isolation

17.8 Models of Speciation

17.9 Macroevolution

Chapter 18: Organizing Information about Species

18.1 Bye Bye Birdie

18.2 Phylogeny

18.3 Comparing Form and Function

18.4 Comparing Molecules

18.5 Comparing Development

18.6 Phylogeny Research

Chapter 19: Life’s Origin and Early Evolution

19.1 Looking for Life

19.2 The Early Earth

19.3 Organic Monomers Form

19.4 From Polymers to Protocells

19.5 The Age of Prokaryotes

19.6 A Rise in Oxygen

19.7 Origin and Evolution of Eukaryotes

Chapter 20: Viruses, Bacteria, and Archaea

20.1 The Human Microbiota

20.2 Virus Structure and Function

20.3 Viral Replication

20.4 Viruses and Human Health

20.5 Prokaryotic Structure and Function

20.6 Metabolic Diversity in Prokaryotes

20.7 Major Bacterial Lineages

20.8 Bacteria as Pathogens

20.9 Archaea

Chapter 21: Protists-The Simplest Eukaryotes

21.1 Malaria: A Protistan Disease

21.2 A Diverse Collection of Lineages

21.4 Stramenopiles

21.5 Alveolates

21.7 Archaeplastids

21.8 Amoebozoans and Opisthokonts

Chapter 22: The Land Plants

22.1 Saving Seeds

22.2 Plant Ancestry and Diversity

22.3 Evolutionary Trends among Plants

22.5 Seedless Vascular Plants

22.6 History of the Vascular Plants

22.7 Gymnosperms

22.8 Angiosperm Traits

22.9 Angiosperm Diversity

Chapter 23: Fungi

23.1 High-Flying Fungi

23.2 Fungal Traits and Diversity

23.3 Flagellated Fungi

23.4 Zygote Fungi and Relatives

23.5 Sac Fungi

23.6 Club Fungi

23.7 Biological Roles of Fungi

Chapter 24: Animal Evolution-The Invertebrates

24.1 Medicines from the Sea

24.2 Animal Traits and Body Plans

24.3 Animal Origins and Diversification

24.4 Sponges

24.5 Cnidarians

24.6 Flatworms

24.7 Annelids

24.8 Mollusks

24.9 Roundworms

24.10 Arthropods

24.11 The Spiny-Skinned Echinoderms

Chapter 25: Animal Evolution-The Vertebrates

25.1 Very Early Birds

25.2 Chordate Traits and Evolutionary Trends

25.3 Fishes

25.4 Amphibians

25.5 Amniote Evolution

25.6 Reptiles

25.7 Birds

25.8 Mammals

Chapter 26: Human Evolution

26.1 A Bit of a Neanderthal

26.2 Primates: Our Order

26.3 Hominoids

26.4 Early Hominins

26.5 Early Humans

26.6 Recent Human Lineages

Chapter 27: Plant Tissues

27.1 Sequestering Carbon in Forests

27.2 The Plant Body

27.3 Plant Tissues

27.4 Stems

27.5 Leaves

27.6 Roots

27.7 Patterns of Growth

Chapter 28: Plant Nutrition and Transport

28.1 Leafy Cleanup

28.2 Plant Nutrients

28.3 Root Adaptations for Nutrient Uptake

28.4 Movement of Water in Plants

28.5 Movement of Organic Compounds in Plants

Chapter 29: Life Cycles of Flowering Plants

29.1 Plight of the Honeybee

29.2 Floral Structure and Function

29.3 A New Generation Begins

29.4 Flower Sex

29.5 Seed Formation

29.6 Fruits

29.7 Early Development

29.8 Asexual Reproduction of Flowering Plants

Chapter 30: Communication Strategies in Plants

30.1 Prescription: Chocolate

30.2 Chemical Signaling in Plants

30.3 Auxin and Cytokinin

30.4 Gibberellin

30.5 Abscisic Acid and Ethylene

30.6 Movement

30.7 Responses to Recurring Environmental Change

30.8 Responses to Stress

Chapter 31: Animal Tissue and Organ Systems

31.1 Making Replacement Cells

31.2 Animal Body Plans

31.3 Epithelial Tissue

31.4 Connective Tissues

31.5 Muscle Tissue

31.6 Nervous Tissue

31.7 Organ Systems

31.8 Human Skin

31.9 Maintaining Homeostasis through Negative Feedback

Chapter 32: Neural Control

32.1 Impacts of Concussions

32.2 Animal Nervous Systems

32.3 Cells of the Nervous System

32.4 Electrical Signaling in Neurons

32.5 Chemical Signaling by Neurons

32.6 Neurotransmitter Function

32.7 The Peripheral Nervous System

32.8 Cells and Tissues of the Central Nervous System

32.9 The Spinal Cord

32.10 The Vertebrate Brain

32.11 The Human Cerebral Cortex

32.12 Emotion and Memory

32.13 Studying Brain Function

Chapter 33: Sensory Perception

33.1 Neuroprostheses

33.2 Overview of Sensory Pathways

33.3 General Senses

33.4 Chemical Senses

33.5 Hearing

33.6 Balance and Equilibrium

33.7 Vision

33.8 Human Vision

Chapter 34: Endocrine Control

34.1 Endocrine Disruptors

34.2 The Vertebrate Endocrine System

34.3 The Nature of Hormone Action

34.4 The Hypothalamus and Pituitary Gland

34.5 The Pineal Gland

34.6 Thyroid and Parathyroid Glands

34.7 Pancreatic Hormones

34.8 The Adrenal Glands

34.9 The Gonads

34.10 Invertebrate Hormones

Chapter 35: Structural Support and Movement

35.1 Bulking Up

35.2 Animal Movement

35.3 Types of Skeletons

35.4 Bone Structure and Function

35.5 Joint Structure and Function

35.6 Skeletal Muscle Function

35.7 How Muscle Contracts

35.8 Nervous Control of Muscle Contraction

35.9 Muscle Metabolism

Chapter 36: Circulation

36.1 A Shocking Save

36.2 Circulatory Systems

36.3 Human Cardiovascular System

36.4 The Human Heart

36.5 Vertebrate Blood

36.6 Arteries and Arterioles

36.7 Blood Pressure

36.8 Exchanges at Capillaries

36.9 Back to the Heart

36.10 Blood and Cardiovascular Disorders

36.11 Interactions with the Lymphatic System

Chapter 37: Immunity

37.1 Community Immunity

37.2 Integrated Responses to Threats

37.3 Surface Barriers

37.4 Mechanisms of Innate Immunity

37.5 Antigen Receptors

37.6 Overview of Adaptive Immunity

37.7 Adaptive Immunity I: An Antibody-Mediated Response

37.8 Adaptive Immunity II: The Cell-Mediated Response

37.9 When Immunity Goes Wrong

Chapter 38: Respiration

38.1 Carbon Monoxide-A Stealthy Poison

38.2 The Nature of Respiration

38.3 Invertebrate Respiration

38.4 Vertebrate Respiration

38.5 Human Respiratory System

38.6 How We Breathe

38.7 Gas Exchange and Transport

38.8 Respiratory Adaptations

38.9 Respiratory Diseases and Disorders

Chapter 39: Digestion and Nutrition

39.1 Breaking It Down

39.2 Animal Digestive Systems

39.3 Human Digestive Tract

39.4 Chewing and Swallowing

39.5 The Stomach

39.6 The Small Intestine

39.7 The Large Intestine

39.8 Nutritional Requirements

39.9 Maintaining a Healthy Weight

Chapter 40: Maintaining the Internal Environment

40.1 Urine Tests

40.2 Fluid Volume and Composition

40.3 Excretory Organs

40.4 The Human Urinary System

40.5 How Urine Forms

40.6 Regulating Solute Levels

40.7 Impaired Kidney Function

40.8 Excretory Adaptations

40.9 Heat Gains and Losses

40.10 Responses to Cold and Heat

Chapter 41: Animal Reproduction

41.1 Assisted Reproduction

41.2 Modes of Animal Reproduction

41.3 Organs of Sexual Reproduction

41.4 Sex Organs of Human Females

41.5 Female Reproductive Cycles

41.6 Sex Organs of Human Males

41.7 Bringing Gametes Together

41.8 Contraception and Infertility

41.9 Sexually Transmitted Diseases

Chapter 42: Animal Development

42.1 Prenatal Problems

42.2 Stages of Animal Development

42.3 From Zygote to Gastrula

42.4 Tissue and Organ Formation

42.5 Evolutionary Developmental Biology

42.6 Overview of Human Development

42.7 Early Human Development

42.8 Emergence of Distinctly Human Features

42.9 Structure and Function of the Placenta

42.10 Labor, Birth, and Lactation

Chapter 43: Animal Behavior

43.1 Can You Hear Me Now?

43.2 Factors Affecting Behavior

43.3 Instinct and Learning

43.4 Movements and Navigation

43.5 Communication Signals

43.6 Mating and Parental Behavior

43.7 Group Living

43.8 Altruism and Eusociality

Chapter 44: Population Ecology

44.1 Managing Canada Geese

44.2 Population Demographics

44.3 Modeling Population Growth

44.4 Limits on Population Growth

44.5 Life History Patterns

44.6 Predation Effects on Life History

44.7 Human Population Growth

Chapter 45: Community Ecology

45.1 Fighting Foreign Fire Ants

45.2 What Factors Shape Community Structure?

45.3 Mutualism

45.4 Competitive Interactions

45.5 Predator-Prey Interactions

45.6 Evolutionary Arms Races

45.7 Parasites and Parasitoids

45.8 How Communities Change

45.9 Biogeographic Patterns in Community Structure

Chapter 46: Ecosystems

46.1 Too Much of a Good Thing

46.2 The Nature of Ecosystems

46.3 The Nature of Food Webs

46.4 Measuring Ecosystem Properties

46.5 Biogeochemical Cycles

46.6 The Water Cycle

46.7 The Carbon Cycle

46.8 Greenhouse Gases and Climate Change

46.9 Nitrogen Cycle

46.10 The Phosphorus Cycle

Chapter 47: The Biosphere

47.1 Going with the Flow

47.2 Global Air Circulation Patterns

47.3 Oceans, Landforms, and Climate

47.4 The El Nino Southern Oscillation

47.5 Biomes

47.6 Deserts

47.7 Grasslands and Dry Shrublands

47.8 Broadleaf Forests

47.9 Coniferous Forests

47.10 Tundra

47.11 Freshwater Ecosystems

47.12 Coastal Ecosystems

47.13 Coral Reefs

47.14 The Open Ocean

Chapter 48: Human Impacts on the Biosphere

48.1 Life in the Anthropocene

48.2 The Extinction Crisis

48.3 Harmful Land Use Practices

48.4 Effects of Pollutants

48.5 Ozone Depletion and Pollution

48.6 Effects of Global Climate Change

48.7 Conservation Biology

48.8 Reducing Negative Impacts

Appendix I: Periodic Table of the Elements

Appendix II: The Amino Acids

Appendix III: A Closer Look at Some Major Metabolic Pathways

Appendix IV: A Plain English Map of the Human Chromosomes

Appendix V: Restless Earth-Life’s Changing Geologic Stage

Appendix VI: Units of Measure

Appendix VII: Answers to Self-Quizzes and Genetics Problems

Glossary of Biological Terms

Index

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Biology the Dynamic Science 3rd Edition PDF

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Biology the Dynamic Science 3rd Edition PDF Download

Biology the Dynamic Science 3rd Edition PDF Download

Biology The Dynamic Science 3Rd Edition Pdf Download

By Peter J Russell, Paul E Hertz and Beverly McMillan

Biology the Dynamic Science 3rd Edition PDF Download. Welcome to the third edition of Biology: The Dynamic Science. The book’s title reflects the speed with which our knowledge of biology is growing. Although biologists have made enormous progress in solving the riddles posed by the living world, every discovery raises new questions and provides new opportunities for further research. As in the prior two editions, we have encapsulated the dynamic nature of biology in the third edition by explaining biological concepts—and the data from which they are derived—in the historical context of each discovery and by describing what we know now and what new discoveries will be likely to advance the field in the future.

Table of Contents

1 Introduction to Biological Concepts and
Research 1
Unit One Molecules and Cells
2 Life, Chemistry, and Water 22
3 Biological Molecules: The Carbon Compounds
of Life 42
4 Energy, Enzymes, and Biological Reactions 71
5 The Cell: An Overview 90
6 Membranes and Transport 119
7 Cell Communication 141
8 Harvesting Chemical Energy: Cellular
Respiration 161
9 Photosynthesis 182
10 Cell Division and Mitosis 205
Unit Two Genetics
11 Meiosis: The Cellular Basis of Sexual
Reproduction 225
12 Mendel, Genes, and Inheritance 239
13 Genes, Chromosomes, and Human Genetics 261
14 DNA Structure, Replication, and Organization 286
15 From DNA to Protein 310
16 Regulation of Gene Expression 339
17 Bacterial and Viral Genetics 369
18 DNA Technologies: Analyzing and Modifying
Genes 391
19 Genomes and Proteomes 416
Unit Three Evolutionary Biology
20 Development of Evolutionary Thought 439
21 Microevolution: Genetic Changes within
Populations 456
22 Speciation 480
23 Paleobiology and Macroevolution 499
24 Systematics and Phylogenetics: Revealing
the Tree of Life 528
Unit Four Biodiversity
25 The Origin of Life 553
26 Prokaryotes: Bacteria and Archaea 567
27 Protists 587
28 Seedless Plants 611
29 Seed Plants 630
30 Fungi 649
31 Animal Phylogeny, Acoelomates, and
Protostomes 670
32 Deuterostomes: Vertebrates and Their Closest
Relatives 706
Unit Five Plant Structure and Function
33 The Plant Body 748
34 Transport in Plants 774
35 Plant Nutrition 793
36 Reproduction and Development in Flowering
Plants 811
37 Plant Signals and Responses to the Environment 838
Unit Six Animal Structure and Function
38 Introduction to Animal Organization and
Physiology 867
39 Information Flow and the Neuron 883
40 Nervous Systems 903
41 Sensory Systems 921
42 The Endocrine System 943
43 Muscles, Bones, and Body Movements 966
44 The Circulatory System 981
45 Defenses against Disease 1002
46 Gas Exchange: The Respiratory System 1024
47 Animal Nutrition 1043
48 Regulating the Internal Environment 1069
49 Animal Reproduction 1096
50 Animal Development 1118
Unit Seven Ecology and Behavior
51 Ecology and the Biosphere 1145
52 Population Ecology 1172
53 Population Interactions and Community Ecology 1199
54 Ecosystems 1229
55 Biodiversity and Conservation Biology 1254
56 Animal Behavior 1278
Appendix A: Answers A-1
Appendix B: Classification System A-36
Glossary G-1
Index I-1

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