Lewin's cells:
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| Vorheriger Titel: | Cells |
|---|---|
| Weitere Verfasser: | |
| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Sudbury, Mass. [u.a.]
Jones and Bartlett
2011
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| Ausgabe: | 2. ed. |
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis |
| Beschreibung: | XXIV, 1053 S. zahlr. Ill. |
| ISBN: | 9780763766641 076376664X |
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| 245 | 1 | 0 | |a Lewin's cells |c lead ed. Lynne Cassimeris ... |
| 246 | 1 | 3 | |a Cells |
| 250 | |a 2. ed. | ||
| 264 | 1 | |a Sudbury, Mass. [u.a.] |b Jones and Bartlett |c 2011 | |
| 300 | |a XXIV, 1053 S. |b zahlr. Ill. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 2 | |a Eukaryotic Cells | |
| 650 | 2 | |a Cells | |
| 650 | 2 | |a Cells Physiology | |
| 650 | 4 | |a Cells | |
| 700 | 1 | |a Cassimeris, Lynne |4 edt | |
| 700 | 1 | |a Lewin, Benjamin |e Begründer eines Werks |4 oth | |
| 780 | 0 | 0 | |i Frühere Auflage |t Cells |
| 856 | 4 | 2 | |m HEBIS Datenaustausch |q application/pdf |u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=027499488&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |3 Inhaltsverzeichnis |
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Datensatz im Suchindex
| _version_ | 1804152495805562880 |
|---|---|
| adam_text | LEWIN S
SECOND EDITION
LEAD EDITORS
Lynne Cassimeris
Lehigh University
Vishwanath R. Lingappa
University of California, San Francisco
Prosetta Bioconformatics, Inc.
George Plopper
JONES AND BARTLETT PUBLISHERS
Sudbury, Massachusetts
BOSTON TORONTO LONDON SINGAPORE
Brief contents
Feature Boxes xvii
Preface xviii
Acknowledgments xxi
Contributors xxii
Abbreviations xxiv
Part 1 Introduction
0 What is a cell? 3
Vishwanath R. Lingappa and Benjamin Lewin
Bioenergetics and cellular metabolism 33
Raymond Ochs and George Plopper
DNA replication, repair, and recombination
Jocelyn E. Krebs
Part 4 The cytoskeleton 501
63
expression and regulation 105
David G. Bear
Protein structure and function
Stephen J. Smerdon
169
Part 2 Membranes and transport
mechanisms 229
Transport of ions and small molecules across
membranes 231
Stephan E. Lehnart and Andrew R. Marks
Membrane targeting of proteins 291
D. Thomas Rutkowski and Vishwanath R. Lingappa
Protein trafficking between membranes 345
Vivek Malhotra, Graham Warren, and Ira Mellman
Part 3 The nucleus 391
Nuclear structure and transport 393
Charles N. Cole and Pamela A. Silver
JChromatin and chromosomes 439
Benjamin Lewin and Jocelyn E. Krebs
Microtubules 503
Lynne Cassimeris
circlecopyrtActin 557
Enrique M. De La Cruz and E. Michael Ostap
Intermediate filaments
Birgit Lane
591
Part 5 Cell division, apoptosis,
and cancer
Mitosis 621
Conly L. Rieder
Cell cycle regulation 673
Kathleen L. Gould and Susan L. Forsburg
^Apoptosis 713
Douglas R. Green
Cancer—Principles and overview 739
Robert A. Weinberg
Part 6 Cell communication
Principles of cell signaling 769
Elliott M. Ross and Melanie H. Cobb
The extracellular matrix and cell adhesion
George Plopper
619
767
821
Part 7 Prokaryotic and plant cells 881
Prokaryotic cell biology 883
Matthew Chapman and Jeff Errington
Plant cell biology 937
Clive Lloyd
Glossary 981
Index 1011
Contents
Feature Boxes xvii
Preface xviii
Acknowledgments xxi
Contributors xxii
Abbreviations xxiv
Part 1 Introduction
What is a cell? 3
Vishwanath R. Lingappa and Benjamin Lewin
Introduction 4
Life began as a self-replicating structure 6
A prokaryotic cell consists of a single
compartment 8
Prokaryotes are adapted for growth under many diverse
conditions 9
A eukaryotic cell contains many membrane-delimited
compartments 10
Membranes allow the cytoplasm to maintain
compartments with distinct environments 11
The nucleus contains the genetic material and is
surrounded by an envelope 12
The plasma membrane allows a cell to maintain
homeostasis 14
Cells within cells: Organelles bounded by envelopes may
have resulted from endosymbiosis 16
DNA is the cellular hereditary material, but there are
other forms of hereditary information 17
Cells require mechanisms to repair damage to DNA 18
Mitochondria are energy factories 19
Chloroplasts power plant cells 19
Organelles require mechanisms for specific localization
of proteins 20
Proteins are transported to and through membranes 21
Protein trafficking moves proteins through the
endoplasmic reticulum and Golgi apparatus 22
Protein folding and unfolding is an essential feature of
all cells 24
The shape of a eukaryotic cell is determined by its
cytoskeleton 24
Localization of cell structures is important 26
Cellular functions: Enzymes, pathways, and
feedback 27
Signal transduction pathways execute predefined
responses 28
All organisms have cells that can grow and divide 29
Differentiation creates specialized cell types,
including terminally differentiated cells 30
References 31
Bioenergetics and cellular
metabolism 33
Raymond Ochs and George Plopper
Introduction 34
Chemical equilibrium and reaction kinetics are
linked 34
The steady state model is essential for understanding
the net flow of reactants in linked reactions 35
Thermodynamics is the systematic treatment of energy
changes 37
Standard free energy, the mass action ratio, and the
equilibrium constant characterize reaction rates in
metabolic pathways 40
Glycolysis is the best understood metabolic
pathway 41
Pyruvate metabolism by the pyruvate dehydrogenase
complex leads to oxidative respiration 44
Fatty acid oxidation is the major pathway of aerobic
energy production 45
The Krebs cycle oxidizes acetyl-CoA and is a metabolic
hub 46
VI
Coupling of chemical reactions is a key feature of living
organisms 48
Oxidative phosphorylation is the final common pathway
converting electron energy to adenosine
triphosphate 49
Photosynthesis completes the carbon cycle by converting
C02 to sugar 54
Nitrogen metabolism encompasses amino acid, protein,
and nucleic acid pathways 56
The Cori cycle and the purine nucleotide cycle are
specialized pathways 57
Metabolic viewpoints provide insight into cellular
regulation—only metabolically reversible reactions are
possible regulatory sites 58
What s next? 59
Summary 60
References 61
DNA replication, repair, and
recombination 63
Jocelyn E. Krebs
Introduction 64
DNA is the genetic material 64
The structure of DNA 66
DNA replication is semiconservative and
bidirectional • 69
DNA polymerases replicate DNA 71
Helicases, single-strand binding proteins, and
topoisomerases are required for replication fork
progression 73
Priming is required to start DNA synthesis 75
A sliding clamp ensures processive DNA replication 76
Leading and lagging strand synthesis is
coordinated 77
Replication initiates at origins and is regulated by the
cell cycle 80
Replicating the ends of a linear chromosome 82
DNA is subject to damage 84
Direct repair can reverse some DNA damage 88
Mismatch repair corrects replication errors 90
Base excision repair replaces damaged bases 92
Nucleotide excision repair removes bulky
DNA lesions 94
Double-strand breaks are repaired by two major
pathways 97
Homologous recombination is used for both repair and
meiotic recombination 99
Summary 102
References 104
4 Gene expression and
regulation 105
David G. Bear
Introduction 106
Genes are transcription units 109
Transcription is a multistep process directed by
DNA-dependent RNA polymerase 111
RNA polymerases are large multisubunit protein
complexes 114
Promoters direct the initiation of transcription 118
Activators and repressors regulate transcription
initiation 122
Transcriptional regulatory circuits control
eukaryotic cell growth, proliferation, and
differentiation 128
The 5 and 3 ends of mature mRNAs are generated by
RNA processing 135
Terminators direct the end of transcription
elongation 138
Introns in eukaryotic pre-mRNAs are removed by the
spliceosome 142
Alternative splicing generates protein diversity 145
Translation is a three-stage process that decodes an
mRNA to synthesize a protein 147
Translation is catalyzed by the ribosome 148
Translation is guided by a large number of protein
factors that regulate the interaction of aminoacylated
tRNAs with the ribosome 152
Translation is controlled by thejnteraction of the 5 and
3 ends of the mRNA and by transLational repressor
proteins 158
Some mRNAs are translated at specific locations within
the cytoplasm 160
Sequence elements in the 5 and 3 untranslated regions
determine the stability of an mRNA 162
Noncoding RNAs are important regulators of gene
expression 164
What s next? 167
Summary 168
References 168
Contents
Protein structure and
function 169
Stephen J. Smerdon
Introduction 170
X-ray crystallography and structural biology 171
Nuclear magnetic resonance 175
Electron microscopy of biomolecules and their
complexes 180
Protein structure representations—a primer 183
Proteins are linear chains of amino acids—primary
structure 185
Secondary structure—the fundamental unit of protein
architecture 190
Tertiary structure and the universe of protein folds 192
Modular architecture and repeating motifs 197
Quaternary structure and higher-order assemblies 200
Enzymes are proteins that catalyze chemical
reactions 204
Posttranslational modifications and cofactors 208
Dynamics, flexibility, and conformational changes 211
Protein-protein and protein-nucleic acid
interactions 214
Function without structure? 219
Structure and medicine 220
What s next? Structural biology in the postgenomic
era 225
Summary 225
References 227
Part 2 Membranes and
transport mechanisms 229
6 Transport of ions and small
molecules across membranes 231
Stephan E. Lehnart and Andrew R. Marks
Introduction 232
Channels and carriers are the main types of membrane
transport proteins 233
Hydration of ions influences their flux through
transmembrane pores 235
Electrochemical gradients across the cell membrane
generate the membrane potential 236
K+ channels catalyze selective and rapid ion
permeation 238
Different K+ channels use a similar gate coupled to
different activating or inactivating mechanisms 242
Voltage-dependent Na+ channels are activated by
membrane depolarization and translate electrical
signals 244
Epithelial Na+ channels regulate Na+ homeostasis 247
Plasma membrane Ca2+ channels activate intracellular
and intercellular signaling processes 250
Cl channels serve diverse biologic functions 252
Selective water transport occurs through aquaporin
channels 256
Action potentials are electrical signals that depend on
several types of ion channels 258
Cardiac and skeletal muscles are activated by excitation-
contraction coupling 260
Some glucose transporters are uniporters 264
Symporters and antiporters mediate coupled
transport 266
The transmembrane Na+ gradient is essential for the
function of many transporters 268
Some Na+ transporters regulate cytosolic or extracellular
pH 271
The Ca2+-ATPase pumps Ca2+ into intracellular storage
compartments 274
The Na+/K+-ATPase maintains the plasma membrane Na+
and K+ gradients 276
The F^-ATP synthase couples H+ movement to ATP
synthesis or hydrolysis 279
H+-ATPases transport protons out of the cytosol 280
What s next? 283
Summary 283
Supplement: Derivation and application of the Nemst
equation 284
Supplement: Most K+ channels undergo
rectification 286
Supplement: Mutations in an aaion channel cause cystic
fibrosis 287
References 289
Membrane targeting of
proteins 291
D. Thomas Rutkowski and Vishwanath R. Lingappa
Introduction 292
Proteins enter the secretory pathway by translocation
across the endoplasmic reticulum membrane (an
overview) 294
vin Contents
Proteins use signal sequences to target to the
endoplasmic reticulum for translocation 296
Signal sequences are recognized by the signal
recognition particle 297
An interaction between signal recognition particle and
its receptor allows proteins to dock at the endopLasmic
reticulum membrane 298
The translocon is an aqueous channel that conducts
proteins 300
Translation is coupled to translocation for most
eukaryotic secretory and transmembrane proteins 303
Some proteins target and translocate
posttranslationally 305
Adenosine triphosphate hydrolysis drives
translocation 306
Transmembrane proteins move out of the translocation
channel and into the lipid bilayer 308
The orientation of transmembrane proteins is determined
as they are integrated into the membrane 309
Signal sequences are removed by signal peptidase 311
The lipid glycosylphosphatidylinositol is added to some
translocated proteins 312
Sugars are added to many translocating proteins 313
Chaperones assist folding of newly translocated
proteins 314
Protein disulfide isomerase ensures the formation of the
correct disulfide bonds as proteins fold 316
The calnexin/calreticulin chaperoning system recognizes
carbohydrate modifications 317
The assembly of proteins into complexes is monitored 318
Terminally misfolded proteins in the endoplasmic
reticulum are returned to the cytosol for
degradation 319
Communication between the endoplasmic reticulum and
nucleus prevents the accumulation of unfolded proteins
in the lumen 322
The endoplasmic reticulum synthesizes the major cellular
phospholipids 324
Lipids must be moved from the endoplasmic reticulum to .
the membranes of other organelles 327
The two leaflets of a membrane often differ in lipid
composition 328
The endoplasmic reticulum is morphologically and
functionally subdivided 328
The endoplasmic reticulum is a dynamic
organelle 330
Signal sequences are also used to target proteins to
other organelles 333
9 Import-into mitochondria begins with signal sequence
recognition at the outer membrane 334
£9 Complexes in the inner and outer membranes cooperate
in mitochondrial protein import 335
H Proteins imported into chloroplasts must also cross two
membranes 337
JEI Proteins fold before they are imported into
peroxisomes 338
II What s next? 339
M Summary 340
References 343
8 Protein trafficking between
membranes 345
Vivek Malhotra, Graham Warren, and Ira Mellman
Introduction 346
Overview of the exocytic pathway 348
Overview of the endocytic pathway 351
Concepts in vesicle-mediated protein transport 355
The concepts of signal-mediated and bulk flow protein
transport 357
Coat protein II-coated vesicles mediate transport from
the ER to the Golgi apparatus 358
Resident proteins that escape from the ER are
retrieved 361
Coat protein I-coated vesicles mediate retrograde
transport from the Golgi apparatus to the ER 362
There are two popular models for forward transport
through the Golgi apparatus 364
Retention of proteins in the Golgi apparatus depends on
the membrane-spanning domain 365
Rab guanosine triphosphate-ases and tethers are two
types of proteins that regulate vesicle targeting 366
Soluble A/-ethymaleimide-sensitive factor attachment
protein receptor proteins likelymediate fusion of
vesicles with target membranes 368
Endocytosis is often mediated by clathrin-coated
vesicles 371
Adaptor complexes link clathrin and transmembrane
cargo proteins 374
Some receptors recycle from early endosomes whereas
others are degraded in lysosomes 376
Early endosomes become late endosomes and lysosomes
by maturation 378
Sorting of lysosomal proteins occurs in the irans-Golgi
network 380
Contents IX
Polarized epithelial cells transport proteins to apical and
basolateral membranes 383
i
Some cells store proteins for later secretion 385
Some proteins are secreted without entering the
ER-Golgi pathway 387
What s next? 388
Summary 388
References 389
Part 3 The nucleus 391
Nuclear structure and
transport 393
Charles N. Cole and Pamela A. Silver
Introduction 394
Nuclei vary in appearance according to cell type and
organism 396
Chromosomes occupy distinct territories 397
The nucleus contains subcompartments that are not
membrane-bounded 398
Some processes occur at distinct nuclear sites and may
reflect an underlying structure 400
The nucleus is bounded by the nuclear envelope 401
The nuclear lamina underlies the nuclear
envelope 403
Large molecules are actively transported between the
nucleus and cytoplasm 405
Nuclear pore complexes are symmetrical channels 406
Nuclear pore complexes are constructed from
nucleoporins 408
Proteins are selectively transported into the nucleus
through nuclear pores 411
Nuclear localization sequences target proteins to the
nucleus 412
Cytoplasmic nuclear localization sequence receptors
mediate nuclear protein import 413
Export of proteins from the nucleus is also
receptor-mediated 415
The Ran GTPase controls the direction of nuclear
transport 417
Multiple models have been proposed for the mechanism
of nuclear transport 419
Nuclear transport can be regulated 421
Multiple classes of RNA are exported from the
nucleus 422
•aw Ribosomal subunits are assembled in the nucleolus and
exported by exportin 1 424
wiwmm tRNAs are exported by a dedicated exportin 425
•aw Messenger RNAs are exported from the nucleus as
RNA-protein complexes 427
mtuitm hnRNPs move from sites of processing to nuclear pore
complexes 429
mtwxm mRNA export requires several novel factors 429
EflXI U snRNAs are exported, modified, assembled into
complexes, and imported 432
KE9 Precursors to microRNAs are exported from the nucleus
and processed in the cytoplasm 433
•awil What s next? 434
References 437
10 Chromatin and chromosomes 439
Benjamin Lewin and Jocelyn E. Krebs
mm Introduction 440
muwm Chromatin is divided into euchromatin and
heterochromatin 441
•BUM Chromosomes have banding patterns 442
muwm Eukaryotic DNA has loops and domains attached to a
scaffold 444
rnunsu Specific sequences attach DNA to an interphase matrix
or a metaphase scaffold 445
•SB The centromere is essential for segregation 446
CED Centromeres have short DNA sequences in
5. cerevisiae 447
U«£| The centromere binds a protein complex 448
BEB Centromeres may contain repetitive DNA 449
USBBj Telomeres are replicated by a special mechanism 450
EESD Lampbrush chromosomes are extended 452
iBMM Polytene chromosomes form bands 453
U!BE| Polytene chromosomes expand at sites of gene
expression 456
USBEJ The nucleosome is the subunit of all chromatin 457
U!S13 DNA is coiled in arrays of nucleosomes 459
USBI3 Nucleosomes have a common structure 460
EESB DNA structure varies on the nucleosomal surface 462
iiiwia Organization of the histone octamer 464
USBfii Histone variants produce alternative nucleosomes 466
Q£E9 The path of nucleosomes in the chromatin fiber 467
Q*EB Reproduction of chromatin requires assembly of
nucleosomes 469
Contents
Do nucleosomes lie at specific positions? 472
Domains define regions that contain active genes 475
Histone octamers are displaced and reassembled during
transcription 476
DNase hypersensitive sites change chromatin
structure 480
Chromatin remodeling is an active process 481
Histone acetylation is associated with transcriptional
activity 485
Heterochromatin propagates from a nucleation
event 488
Heterochromatin depends on interactions with
histones 489
X chromosomes undergo global changes 492
Chromosome condensation is caused by
condensins 494
What s next? 497
Summary 497
References 500
Part 4 The cytoskeleton 501
11
iim
BH
HUM
Microtubules 503
Lynne Cassimeris
Introduction 504
General functions of microtubules 506
Microtubules are polar polymers of a- and
P-tubulin 509
Purified tubulin subunits assemble into
microtubules 511
Microtubule assembly and disassembly proceed by a
unique process termed dynamic instability 513
A cap of GTP-tubulin subunits regulates the transitions
of dynamic instability 515
Cells use microtubule-organizing centers to nucleate
microtubule assembly 517
Microtubule dynamics in cells 520
Why do cells have dynamic microtubules? 523
Cells use several classes of proteins to regulate the
stability of their microtubules 525
Introduction to microtubule-based motor proteins 529
How motor proteins work 532
How cargoes are loaded onto the right motor 537
Microtubule dynamics and motors combine to generate
the asymmetric organization of cells 539
EESS Interactions between microtubules and actin
filaments 543
UB£J Cilia and flagella are motile structures 545
0X9 What s next? 550
i»KEl Summary 551
UBEJ Supplement: What if tubulin did not hydrolyze
GTP? 552
nwm Supplement: Fluorescence recovery after
photobleaching 553
•mai Supplement: Tubulin synthesis and modification
References 555
554
12 Actin 557
Enrique M. De La Cruz and E. Michael Ostap
Introduction 558
Actin is a ubiquitously expressed cytoskeletal
protein 559
Actin monomers bind ATP and ADP 559
Actin filaments are structurally polarized polymers 560
Actin polymerization is a multistep and dynamic
process 561
Actin subunits hydrolyze ATP after polymerization 564
Actin-binding proteins regulate actin polymerization and
organization 566
Actin monomer-binding proteins influence
polymerization 567
Nucleating proteins control cellular actin
polymerization 568
Capping proteins regulate the length of actin
filaments 569
Severing and depolymerizing proteins regulate actin
filament dynamics 570
Cross-linking proteins organize actin filaments into
bundles and orthogonal networks 571
Actin and actin-binding proteins work together to drive
cell migration 572
Small G proteins regulate actin polymerization 574
Myosins are actin-based molecular motors with essential
roles in many cellular processes 576
Myosins have three structural domains 579
ATP hydrolysis by myosin is a muLtistep reaction 582
Myosin motors have kinetic properties suited for their
cellular roles 583
Myosins take nanometer steps and generate piconewton
forces 584
Myosins are regulated by multiple mechanisms 585
Contents
13
Myosin-II functions in muscle contraction 586
What s next? 589
Summary 590
References 590
Intermediate filaments.... 591
Birgit Lane
Introduction 592
Similarities in structure define the intermediate filament
family 593
Intermediate filament subunits assemble with high
affinity into strain-resistant structures 595
Two-thirds of all intermediate filament proteins are
keratins 598
Mutations in keratins cause epithelial cell fragility 602
Intermediate filament proteins of nerve, muscle, and
connective tissue often show overlapping
expression 603
Lamin intermediate filaments reinforce the nuclear
envelope 606
Even the.divergent lens filament proteins are conserved
in evolution 608
Posttranslational modifications regulate and remodel
intermediate filament networks 608
Interacting proteins facilitate secondary functions of
intermediate filaments 611
Intermediate filament genes are represented through
metazoan evolution 612
What s next? 614
Summary 615
References 616
Part 5 Cell division,
apoptosis, and cancer 619
14 Mitosis 621
Conly L. Rieder
Introduction 622
Mitosis is divided into stages 625
Mitosis requires the formation of a new apparatus called
the spindle 627
Spindle formation and function depend on the dynamic
behavior of microtubules and their associated motor
proteins 630
tarn
8EHH
(WH
Centroso mes are microtubule organizing centers 632
Centrosomes reproduce about the time the DNA is
replicated 633
Spindles begin to form as separating asters interact 636
Spindles require chromosomes for stabilization but can
self-organize without centrosomes 638
The centromere is a specialized region on the
chromosome that contains the kinetochores 640
Kinetochores form at the onset of prometaphase and
contain microtubule motor proteins 641
Kinetochores capture and stabilize their associated
microtubules 642
Mistakes in kinetochore attachment are
corrected 646
Kinetochore fibers must both shorten and elongate to
allow chromosomes to move 649
The force to move a chromosome toward a pole is
produced by two mechanisms 651
Congression involves pulling forces that act on the
kinetochores 652
Congression is also regulated by forces that act along
the chromosome arms and the activity of sister
kinetochores 654
Kinetochores control the metaphase/anaphase
transition 656
Anaphase has two phases 658
Changes occur during telophase that lead the cell out of
the mitotic state 660
During cytokinesis, the cytoplasm is partitioned to form
two new daughter cells 662
Formation of the contractile ring requires the spindle
and stem bodies 664
The contractile ring cleaves the cell in two 667
The segregation of nonnuclear organelles during
cytokinesis is based on chance 668
What s next? 669
Summary 670
References 670
15 Cell cycle regulation 673
Kathleen L. Gould and Susan L. Forsburg
Introduction 674
Several experimental systems are used for cell cycle
research 676
Events of the cell cycle are coordinated 679
XI1 Contents
rang
ram
A cycle of cyclin-dependent kinase activities regulates
cell proliferation 680
Cyclin-dependent kinases-cyclin complexes are regulated
in several ways 683
Cells may withdraw from the cell cycle 685
Entry into cell cycle is tightly regulated 687
DNA replication requires the ordered assembly of protein
complexes 689
Mitosis is orchestrated by several protein kinases 692
Sister chromatids are held together until anaphase 694
Exit from mitosis requires more than cyclin
proteolysis 696
Checkpoint controls coordinate different cell cycle
events 699
DNA replication and DNA damage checkpoints monitor
defects in DNA metabolism 701
The spindle assembly checkpoint monitors defects in
chromosome-microtubule attachment 705
Cell cycle deregulation can lead to cancer 707
What s next? 708
Summary 710
References 710
16 Apoptosis 713
Douglas R. Green
Introduction 714
Caspases orchestrate apoptosis by cleaving specific
substrates 716
Executioner caspases are activated by cleavage, whereas
initiator caspases are activated by dimerization 717
Some inhibitors of apoptosis proteins block
caspases 718
Some caspases have functions in inflammation 719
The death receptor pathway of apoptosis transmits
external signals 720
Apoptosis signaling by tumor necrosis factor receptor 1
is complex 722
The mitochondrial pathway of apoptosis 723
Bcl-2 family proteins mediate and regulate
mitochondrial outer membrane permeabilization
and apoptosis 724
The multidomain Bcl-2 proteins Bax and Bak are required
for mitochondrial outer membrane
permeabilization 725
The activation of Bax and Bak are controlled by other
Bcl-2 family proteins 726
nun
am Cytochrome c, released upon mitochondrial outer
membrane permeabilization, induces caspase
activation 727
SB Some proteins released upon mitochondrial outer
membrane permeabilization block inhibitors of apoptosis
proteins 728
SQ The death receptor pathway of apoptosis can engage
mitochondrial outer membrane permeabilization through
the cleavage of the BH3-only protein Bid 728
SB Mitochondrial outer membrane permeabilization can
cause caspase-independent cell death 729
SB The mitochondrial permeability transition can cause
mitochondrial outer membrane permeabilization 730
SQ Many discoveries about apoptosis were made in
nematodes 731
Mm Apoptosis in insects has features distinct from mammals
and nematodes 732
SB The clearance of apoptotic cells requires cellular
interaction 733
SB Apoptosis plays a role in diseases such as viral infection
and cancer 734
am Apoptotic cells are gone but not forgotten 735
SB What s next? 736
»*l Summary 737
References 737
17 Cancer—Principles and
overview 739
Robert A. Weinberg
Tumors are masses of cells derived from a single
cell 740
Cancer cells have a number of phenotypic
characteristics 741
Cancer cells arise after DNA damage 744
Cancer cells are created when certain genes are
mutated 745
Cellular genomes harbor a number of protooncogenes 747
Elimination of tumor suppressor activity requires two
mutations 749
The genesis of tumors is a complex process 750
Cell growth and proliferation are activated by growth
factors 753
Cells are subject to growth inhibition and may exit from
the cell cycle 755
Tumor suppressors block inappropriate entry into the cell
cycle 757
ItHM
Contents xm
UttU Mutation of DNA repair and maintenance genes can
increase the overall mutation rate 758
tlfiEJ Cancer cells may achieve immortality 760
UBS Access to vital supplies is provided by
angiogenesis 761
QKQ Cancer cells may invade new locations in the body 762
WSS What s next? 763
EQEB Summary 764
References 765
Part 6 Cell
communication 767
18 Principles of cell signaling.. 769
Elliott M. Ross and Melanie H. Cobb
Introduction 770
Cellular signaling is primarily chemical 771
Receptors sense diverse stimuli but initiate a limited
repertoire of cellular signals 772
Receptors are catalysts and amplifiers 773
Ligand binding changes receptor conformation 773
Signals are sorted and integrated in signaling pathways
and networks 775
Cellular signaling pathways can be thought of as
biochemical logic circuits 777
Scaffolds increase signaling efficiency and enhance
spatial organization of signaling 779
Independent, modular domains specify protein-protein
interactions 780
Cellular signaling is remarkably adaptive 782
Signaling proteins are frequently expressed as multiple
species 784
Activating and deactivating reactions are separate and
independently controlled 786
Cellular signaling uses both allostery and covalent
modification 786
Second messengers provide readily diffusible pathways
for information transfer 786
Ca2+ signaling serves diverse purposes in all eukaryotic
cells 788
Lipids and lipid-derived compounds are signaling
molecules 790
PI 3-kinase regulates both cell shape and the activation
of essential growth and metabolic functions 792
Signaling through ion channel receptors is very
fast 793
EB Nuclear receptors regulate transcription 794
WBl G protein-signaling modules are widely used and highly
adaptable 795
EQ Heterotrimeric G proteins regulate a wide variety of
effectors 798
EB Heterotrimeric G proteins are controlled by a regulatory
GTPase cycle 799
E3 Small, monomeric GTP-binding proteins are multiuse
switches 800
E9 Protein phosphorylation/dephosphorylation is a major
regulatory mechanism in the cell 802
EJB Two-component protein phosphorylation systems are
signaling relays 805
EB Pharmacologic inhibitors of protein kinases may be used
to understand and treat disease 805
ED Phosphoprotein phosphatases reverse the actions of
kinases and are independently regulated 807
EB Covalent modification by ubiquitin and ubiquitin-like
proteins is another way of regulating protein
function 808
EB The Wnt pathway regulates cell fate during development
and other processes in the adult 810
SB Diverse signaling mechanisms are regulated by protein
tyrosine kinases 810
EQ Src family protein kinases cooperate with receptor
protein tyrosine kinases 812
E9 Mitogen-activated protein kinases are central to many
signaling pathways 813
S3 Cyclin-dependent protein kinases control the cell
cycle 814
EQ Diverse receptors recruit protein-tyrosine kinases to the
plasma membrane 815
SB What s next? 818
EB Summary 819
References 819
19 The extracellular matrix and cell
adhesion 821
George Plopper
Introduction 822
Collagen provides structural support to tissues 825
Fibronectins connect cells to collagenous matrices 829
Elastic fibers impart flexibility to tissues 831
Laminins provide an adhesive substrate for cells 833
Vitronectin facilitates targeted cell adhesion during
blood clotting 836
xw Contents
Matricellular proteins regulate cell-extracellular matrix
interactions 837
Proteoglycans provide hydration to tissues 839
Hyaluronan is a glycosaminoglycan enriched in
connective tissues 841
Heparan sulfate proteoglycans are cell surface
coreceptors 843
The basal lamina is a specialized extracellular
matrix 846
Proteases degrade extracellular matrix components 847
Most integrins are receptors for extracellular matrix
proteins 850
Integrin receptors participate in cell signaling 853
Integrins and extracellular matrix molecules play key
roles in development 857
Tight junctions form selectively permeable barriers
between cells 859
Septate junctions in invertebrates are similar to tight
junctions 862
Adherens junctions link adjacent cells 864
Desmosomes are intermediate filament-based cell
adhesion complexes 866
Hemidesmosomes attach epithelial cells to the basal
lamina 867
Gap junctions allow direct transfer of molecules between
adjacent cells 869
Calcium-dependent cadherins mediate adhesion between
cells 871
Calcium-independent neural cell adhesion molecules
mediate adhesion between neural cells 874
Selectins control adhesion of circulating immune
cells 876
What s next? 877
Summary 878
References 878
Part 7 Prokaryotic and
plant cells 881
20 Prokaryotic cell biology 883
Matthew Chapman and Jeff Errington
3SH Introduction 884
S!H Molecular phylogeny techniques are used to understand
microbial evolution 886
33fl Prokaryotic lifestyles are diverse 888
21
Archaea are prokaryotes with similarities to eukaryotic
cells 890
Most prokaryotes produce a polysaccharide-rich layer
called the capsule 892
The bacteriaL cell wall contains a cross-linked meshwork
of peptidoglycan 894
The cell envelope of Gram-positive bacteria has unique
features 898
Gram-negative bacteria have an outer membrane and a
periplasmic space 901
The cytoplasmic membrane is a selective barrier for
secretion 903
Prokaryotes have several secretion pathways 905
|
| any_adam_object | 1 |
| author2 | Cassimeris, Lynne |
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| building | Verbundindex |
| bvnumber | BV042058569 |
| ctrlnum | (OCoLC)891227373 (DE-599)HBZHT016309517 |
| edition | 2. ed. |
| format | Book |
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| id | DE-604.BV042058569 |
| illustrated | Illustrated |
| indexdate | 2024-07-10T01:11:38Z |
| institution | BVB |
| isbn | 9780763766641 076376664X |
| language | English |
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| oclc_num | 891227373 |
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| owner_facet | DE-20 |
| physical | XXIV, 1053 S. zahlr. Ill. |
| publishDate | 2011 |
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| publishDateSort | 2011 |
| publisher | Jones and Bartlett |
| record_format | marc |
| spelling | Lewin's cells lead ed. Lynne Cassimeris ... Cells 2. ed. Sudbury, Mass. [u.a.] Jones and Bartlett 2011 XXIV, 1053 S. zahlr. Ill. txt rdacontent n rdamedia nc rdacarrier Eukaryotic Cells Cells Physiology Cassimeris, Lynne edt Lewin, Benjamin Begründer eines Werks oth Frühere Auflage Cells HEBIS Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=027499488&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Lewin's cells Eukaryotic Cells Cells Cells Physiology |
| title | Lewin's cells |
| title_alt | Cells |
| title_auth | Lewin's cells |
| title_exact_search | Lewin's cells |
| title_full | Lewin's cells lead ed. Lynne Cassimeris ... |
| title_fullStr | Lewin's cells lead ed. Lynne Cassimeris ... |
| title_full_unstemmed | Lewin's cells lead ed. Lynne Cassimeris ... |
| title_old | Cells |
| title_short | Lewin's cells |
| title_sort | lewin s cells |
| topic | Eukaryotic Cells Cells Cells Physiology |
| topic_facet | Eukaryotic Cells Cells Cells Physiology |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=027499488&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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