| |
Preface |
5 |
|
| |
References |
11 |
|
| |
Note Added in Proof |
11 |
|
| |
References |
12 |
|
| |
Contents |
13 |
|
| |
Contents of Volume 2: Recombination and Meiosis |
20 |
|
| |
Evolution of Models of Homologous Recombination |
21 |
|
| |
1 Introduction |
21 |
|
| |
2 Robin Holliday’s Remarkable Model |
27 |
|
| |
3 Molecular Models Based on a Single Initiating DNA Lesion |
33 |
|
| |
4 The Meselson–Radding Model (1975) |
35 |
|
| |
5 Problems with the Meselson–Radding Model |
39 |
|
| |
6 Alternative Ways to Initiate Recombination |
40 |
|
| |
7 The Double Holliday DSB Repair Model of Szostak, Orr- Weaver, Rothstein and Stahl |
45 |
|
| |
8 Identification of DNA Intermediates of Recombination |
48 |
|
| |
9 Multiple Pathways Meiotic Recombination |
55 |
|
| |
10 Single-Strand Annealing Causes Primarily Intrachromosomal Deletions |
58 |
|
| |
11 Synthesis-Dependent Strand Annealing Accounts for Most Mitotic Recombination and Noncrossovers in Meiosis |
59 |
|
| |
12 Evolution of Gene Conversion Models in the Present |
65 |
|
| |
13 Another Major Source of Creative Thinking: Nonreciprocal Recombination in Phage . |
68 |
|
| |
14 Re-Emergence of Old Ideas in New Guises: Break-Induced Replication |
69 |
|
| |
References |
72 |
|
| |
Searching for Homology by Filaments of RecA- Like Proteins |
85 |
|
| |
1 RecA-Like Proteins and Homologous Recombination |
85 |
|
| |
2 Sequence Effects in Homologous Recombination |
92 |
|
| |
3 Homology Search in the Cell |
94 |
|
| |
4 Models of Homology Search at the Molecular Level |
96 |
|
| |
5 Homology Recognition at the Atomic Level |
100 |
|
| |
6 Conclusion |
104 |
|
| |
References |
104 |
|
| |
Biochemistry of Meiotic Recombination: Formation, Processing, and Resolution of Recombination Intermediates |
110 |
|
| |
1 Introduction |
111 |
|
| |
2 Biochemistry of Meiotic Recombination |
114 |
|
| |
3 Conclusions and Outlook |
167 |
|
| |
References |
169 |
|
| |
Meiotic Chromatin: The Substrate for Recombination Initiation |
184 |
|
| |
1 Introduction |
184 |
|
| |
2 Double-Strand Breaks and Chromatin Structure in Saccharomyces cerevisiae |
186 |
|
| |
3 Recombination Hotspots and Chromatin Structure in Schizosaccharomyces pombe |
196 |
|
| |
4 Hints from Multicellular Organisms |
201 |
|
| |
References |
205 |
|
| |
Meiotic Recombination in Schizosaccharomyces pombe: A Paradigm for Genetic andMolecular Analysis |
213 |
|
| |
1 S. pombe: An Excellent Model Organism for Studying Meiotic Recombination |
214 |
|
| |
2 Overview: A Pathway for S. pombe Meiotic Recombination |
215 |
|
| |
3 Nuclear Movement Promotes Chromosome Alignment: “ Bouquet” and “ Horsetail” Formation |
217 |
|
| |
4 Meiosis-specific Sister Chromatid Cohesins: Behavior Change |
220 |
|
| |
5 DSB Formation by Rec12: Preparation and Partnership |
221 |
|
| |
6 DSB Hotspots and Coldspots: Regulating Where Recombination Occurs |
226 |
|
| |
7 Processing of Rec12-generated DSBs: Converting a Lesion into a Recombinogenic DNA-Protein Complex |
229 |
|
| |
8 Strand Invasion and Partner Choice |
233 |
|
| |
9 Joint Molecule Resolution |
235 |
|
| |
10 Mismatch Correction |
237 |
|
| |
11 Relation of Gene Conversion and Crossing-over |
238 |
|
| |
12 Species-specific Strategies for Ensuring, With or Without Interference, the Crossovers Required for Chromosome Segregation |
239 |
|
| |
13 Differences Between S. pombe and S. cerevisiae Meiotic Recombination: A Reprise |
240 |
|
| |
References |
242 |
|
| |
Nuclear Movement Enforcing Chromosome Alignment in Fission Yeast— Meiosis Without Homolog Synapsis |
249 |
|
| |
1 Introduction |
249 |
|
| |
2 Alignment of Homologous Chromosomes |
251 |
|
| |
3 Regulation of Telomere Clustering |
255 |
|
| |
4 Regulation of Nuclear Movement |
259 |
|
| |
5 Conclusion and Outlook |
261 |
|
| |
References |
262 |
|
| |
On the Origin of Meiosis in Eukaryotic Evolution: Coevolution of Meiosis and Mitosis from Feeble Beginnings |
266 |
|
| |
1 Introduction |
267 |
|
| |
2 A Conserved Core of Meiotic Proteins |
269 |
|
| |
3 The Complex Eukaryotic Signature |
270 |
|
| |
4 The Universal Trifurcation |
272 |
|
| |
5 The RNA World Scenario |
274 |
|
| |
6 Dynamic Implications of Eigen’s Quasi-Species Concept |
278 |
|
| |
7 Woese’s Phase Shift at Decreasing “Evolutionary Temperature” |
280 |
|
| |
8 Early Traits with Preadaptive Value for Meiosis |
284 |
|
| |
9 Meiosis vs. Mitosis – Alternative Programs Responding to Different Selective Needs |
288 |
|
| |
10 Coevolution of Meiosis and Mitosis |
291 |
|
| |
11 Variations on the Meiotic System in the World of Protists |
294 |
|
| |
12 Concluding Remarks |
297 |
|
| |
References |
300 |
|
| |
The Legacy of the Germ Line – Maintaining Sex and Life in Metazoans: Cognitive Roots of the Concept of Hierarchical Selection |
306 |
|
| |
1 Introduction |
306 |
|
| |
2 The Legacy of the Germ Line |
308 |
|
| |
3 The Allmacht of Selection |
329 |
|
| |
4 Maintaining Sex in Metazoans |
336 |
|
| |
5 Finale |
346 |
|
| |
References |
350 |
|
| |
Lessons to Learn from Ancient Asexuals |
357 |
|
| |
1 The Paradox of Sex |
357 |
|
| |
2 What is an Ancient Asexual? |
361 |
|
| |
3 Novel Genetic Tests – Meiosis Proteins |
379 |
|
| |
4 Conclusions |
381 |
|
| |
References |
383 |
|
| |
Subject Index |
393 |
|
