|
Introduction
|
9 |
1.
|
Metaphysical foundations of science
|
11 |
| 1.1 |
What is knowledge? |
11 |
| 1.2 |
Classification and the function of language |
12 |
| 1.3 |
What is there outside of our cognition apparatus? What is “really existing”? |
16 |
| 1.3.1 |
Objects of nature, the “thing per se” |
17 |
| 1.3.2 |
Systems |
18 |
| 1.3.3 |
Thing and system |
19 |
| 1.3.4 |
What is a “system in the animal kingdom”? |
20 |
| 1.3.5 |
What is “information”? |
21 |
| 1.3.6 |
Quantifying information |
24 |
| 1.3.7 |
What is a character? |
25 |
| 1.4 |
Acquisition of knowledge in sciences |
29 |
| 1.4.1 |
What is a “truth”? |
29 |
| 1.4.2 |
Deduction and induction |
30 |
| 1.4.3 |
The hypothetico-deductive method |
32 |
| 1.4.4 |
Laws and theories |
34 |
| 1.4.5 |
Probability and the principle of parsimony |
34 |
| 1.4.6 |
Phenomenology |
40 |
| 1.4.7 |
The role of logic |
41 |
| 1.4.8 |
Algorithms and gaining knowledge |
41 |
| 1.5 |
Evolutionary epistemology |
42 |
2.
|
The subject of phylogenetic systematics
|
44 |
| 2.1 |
Transfer of genetic information between organisms |
45 |
| 2.1.1 |
Horizontal gene transfer |
45 |
| 2.1.2 |
Clonal reproduction |
45 |
| 2.1.3 |
Bisexual reproduction |
46 |
| 2.1.4 |
The special case of endosymbionts which evolved to organelles (mitochondria and plastids) |
47 |
| 2.2 |
The population |
48 |
| 2.3 |
The “biological species” |
52 |
| 2.3.1 |
The species concept as a tool of phylogenetics |
56 |
| 2.3.2 |
Recognition of species |
63 |
| 2.4 |
The transitional field between species |
65 |
| 2.5 |
Speciation as a “key event” |
68 |
| 2.5.1 |
Notions and real processes |
68 |
| 2.5.2 |
Dichotomy and polytomy |
68 |
| 2.6 |
Monophyla |
69 |
| 2.7 |
Evolutionary theory and models of evolution as basis for systematics |
73 |
| 2.7.1 |
Variability and evolution of morphological structures |
75 |
| 2.7.2 |
Variability and evolution of molecules |
81 |
| 2.7.2.1 |
Changes in populations |
81 |
| 2.7.2.2 |
The theory of neutral evolution |
83 |
| 2.7.2.3 |
The molecular clock |
85 |
| 2.7.2.4 |
Evolutionary rates |
89 |
| 2.8 |
Summary: Constructs, processes and systems |
97 |
3.
|
Phylogenetic graphs
|
98 |
| 3.1 |
Ontology and terms |
98 |
| 3.2 |
Topology |
100 |
| 3.2.1 |
Visualization of compatible hypotheses of monophyly |
100 |
| 3.2.2 |
Visualization of incompatible hypotheses of monophyly |
103 |
| 3.2.3 |
Visualization of hypotheses of character polarity and of apomorphy |
103 |
| 3.3 |
Consensus dendrograms |
104 |
| 3.3.1 |
Supertrees and “democratic voting” |
106 |
| 3.4 |
Number of elements of a dendrogram and number of topologies |
107 |
| 3.5 |
The taxon |
108 |
| 3.6 |
The stem lineage |
111 |
| 3.7 |
Linnéan categories |
113 |
4.
|
The search for evidence of monophyly
|
177 |
| 4.1 |
What is information in systematics? |
177 |
| 4.2 |
Classes of characters |
119 |
| 4.2.1 |
Similarities |
119 |
| 4.2.2 |
Classes of homologies |
124 |
| 4.2.3 |
Forming groups with different classes of characters |
132 |
| 4.2.4 |
Homologous genes |
133 |
| 4.3 |
Principles of character analysis |
134 |
| 4.3.1 |
Processes and patterns, or what we can learn from Leonardo’s Mona Lisa |
135 |
| 4.4 |
Delimitation and identification of monophyla |
137 |
| 4.4.1 |
The delimitation |
137 |
| 4.4.2 |
The identification |
139 |
| 4.4.3 |
Recommended procedure for practical analyses |
139 |
| 4.5 |
Analysis of fossils |
139 |
| 4.5.1 |
Character analysis |
139 |
| 4.5.2 |
Transformation series of populations as evidence for monophyly |
141 |
5.
|
Phenomenological character analysis
|
142 |
| 5.1 |
The estimation of the probability of homology and character weighting |
142 |
| 5.1.1 |
The probability of homology and criteria for its evaluation |
142 |
| 5.1.2 |
Weighting |
152 |
| 5.2 |
The search for morphological and molecular homologies |
155 |
| 5.2.1 |
Criteria of homology for morphological characters |
155 |
| 5.2.2 |
Homologization of molecular characters |
164 |
| 5.2.2.1 |
Sequence alignment |
164 |
| 5.2.2.2 |
Determination of the homology of nucleotides and of sequence sections |
169 |
| 5.2.2.3 |
Homology of genes, gene arrangements, sequence duplications |
171 |
| 5.2.2.4 |
Homology of restriction fragments |
172 |
| 5.2.2.5 |
Immunology |
174 |
| 5.2.2.6 |
Homologization of isoenzymes |
175 |
| 5.2.2.7 |
Cytogenetics |
177 |
| 5.2.2.8 |
DNA-Hybridization |
177 |
| 5.2.2.9 |
RAPD and AFLP |
179 |
| 5.2.2.10 |
Amino acid sequences |
180 |
| 5.3 |
Determination of character polarity |
181 |
| 5.3.1 |
Ingroup and outgroup |
181 |
| 5.3.2 |
Phylogenetic character analysis with outgroup comparison, reconstruction of ground patterns |
182 |
| 5.3.3 |
Cladistic outgroup addition |
187 |
| 5.3.4 |
Increase of complexity |
188 |
| 5.3.5 |
The ontogenetic criterion |
189 |
| 5.3.6 |
The paleontological criterion |
192 |
| 5.3.7 |
Phenomenological determination of character state polarity in nucleic acid sequences and asymmetry of split-supporting patterns |
193 |
6.
|
Reconstruction of phylogeny: the phenomenological method
|
195 |
| 6.1 |
Phenetic cladistics |
196 |
| 6.1.1. |
Character coding |
198 |
| 6.1.2. |
The MP-method for tree construction |
201 |
| 6.1.2.1 |
Wagner parsimony |
203 |
| 6.1.2.2 |
Fitch parsimony |
204 |
| 6.1.2.3 |
Dollo parsimony |
204 |
| 6.1.2.4 |
Generalized parsimony |
205 |
| 6.1.2.5 |
Nucleic acids and amino acid sequences |
206 |
| 6.1.3 |
Weighting and the MP-method |
207 |
| 6.1.4 |
Iterative weighting |
208 |
| 6.1.5 |
Homoplasy |
209 |
| 6.1.6 |
Manipulation of the data matrix |
210 |
| 6.1.7 |
Cladistic reconstruction of ground patterns |
210 |
| 6.1.8 |
Rooting of unpolarized dendrograms |
212 |
| 6.1.9 |
Cladistic statistics and tests of reliability |
213 |
| 6.1.9.1 |
Consistency index, retention-index, F-ratio |
213 |
| 6.1.9.2 |
Resampling tests |
215 |
| 6.1.9.3 |
Distribution of tree lengths, randomization tests |
217 |
| 6.1.10 |
Can homologies be identified with the MP-method? |
218 |
| 6.1.11 |
Sources of errors of phenetic cladistics |
220 |
| 6.2 |
Hennig’s method (phylogenetic cladistics) |
222 |
| 6.2.1 |
Comparison of phenetic and phylogenetic cladistics |
224 |
| 6.3 |
Cladistic analysis of DNA-sequences |
225 |
| 6.3.1 |
Model-dependent weighting |
225 |
| 6.3.2 |
The analogy problem: the creation of polyphyletic groups |
228 |
| 6.3.3 |
The symplesiomorphy trap: paraphyletic groups |
230 |
| 6.3.4 |
Using alignment gaps |
231 |
| 6.3.5 |
Potential apomorphies |
236 |
| 6.3.6 |
Lake’s method |
236 |
| 6.4 |
Split-decomposition |
236 |
| 6.5 |
Spectra |
238 |
| 6.5.1 |
Basics |
238 |
| 6.5.2 |
Analysis of spectra of supporting positions |
238 |
| 6.6 |
Combined analyses, data partitioning, total evidence |
242 |
7.
|
Process-based character analysis
|
245 |
8.
|
Reconstruction of phylogeny: model-dependent methods
|
248 |
| 8.1 |
Substitution models |
248 |
| 8.2 |
Distance methods |
254 |
| 8.2.1 |
The principle of distance analyses |
255 |
| 8.2.2 |
Visible distances |
257 |
| 8.2.3 |
Falsifying effects |
259 |
| 8.2.4 |
Effect of invariable positions, positions with different variability, alignment gaps |
260 |
| 8.2.5 |
Effects of nucleotide frequencies |
262 |
| 8.2.6 |
Distance corrections |
262 |
| 8.2.7 |
Tree construction with distance data |
264 |
| 8.3 |
Maximum Likelihood: Estimation of the probability of events |
265 |
| 8.4 |
Bayesian phylogeny inference |
267 |
| 8.5 |
Hendy-Penny spectral analysis |
270 |
| 8.6 |
The role of simulations |
272 |
9.
|
Sources of error
|
273 |
| 9.1 |
Overview of common sources of error |
273 |
| 9.2 |
Criteria for the evaluation of the quality of datasets |
275 |
10.
|
Comparison of topologies and plausibility tests
|
277 |
| 10.1 |
Plausibility |
277 |
| 10.2 |
Comparison of topologies |
287 |
11.
|
The importance of results of phylogenetics for other studies
|
289 |
12.
|
Systematization and classification
|
290 |
| 12.1 |
Systematization |
290 |
| 12.2 |
Hierarchy |
291 |
| 12.3 |
Formal classification |
292 |
| 12.3.1 |
Traditional Linnéan nomenclature |
292 |
| 12.3.2 |
Phylogenetic nomenclature |
294 |
| 12.4 |
Artifacts of the formal classification |
295 |
| 12.5 |
Taxonomy |
296 |
| 12.6 |
Evolutionary taxonomy |
296 |
13.
|
General laws of phylogenetic systematics
|
298 |
14.
|
Appendix: Methods and terms
|
299 |
| 14.1 |
Models of sequence evolution |
299 |
| 14.1.1 |
Jukes-Cantor (JC) model |
299 |
| 14.1.2 |
Tajima-Nei-(TjN-)model |
301 |
| 14.1.3 |
Kimura’s two-parameter-Model (K2P) |
301 |
| 14.1.4 |
Tamura-Nei-model (TrN) |
302 |
| 14.1.5 |
Position-dependent variability of substitution rates |
302 |
| 14.1.6 |
Log-det distance transformation |
304 |
| 14.1.7 |
Protein coding sequences |
305 |
| 14.2 |
Maximum parsimony: the search for the shortest topology |
305 |
| 14.2.1 |
Construction of topologies |
306 |
| 14.2.2 |
Combinatorial weighting |
308 |
| 14.2.3 |
Comparison of MP and ML |
309 |
| 14.3 |
Distance methods |
309 |
| 14.3.1 |
Definition of the Hamming distance |
310 |
| 14.3.2 |
Transformation of distances |
310 |
| 14.3.3 |
Additive distances |
312 |
| 14.3.4 |
Ultrametric distances |
313 |
| 14.3.5 |
Transformation of frequency data to distance data: geometric distances |
313 |
| 14.3.6 |
Nei’s genetic distance: allele frequencies, restriction fragments |
314 |
| 14.3.7 |
Construction of dendrograms with clustering methods |
315 |
| 14.3.8 |
Construction of dendrograms with minimum evolution methods |
317 |
| 14.4 |
Construction of networks: split-decomposition |
317 |
| 14.5 |
Clique analyses |
323 |
| 14.6 |
Maximum likelihood methods: analysis of DNA sequences |
324 |
| 14.7 |
Hadamard conjugation and Hendy-Penny spectra |
328 |
| 14.8 |
Relative rate test |
333 |
| 14.9 |
Evaluation of the information content of datasets using permutations |
335 |
| 14.10 |
F-ratio |
337 |
| 14.11 |
PAM-matrix |
338 |
| 14.12 |
Optimization alignment |
339 |
15.
|
Available computer programs, web sites
|
343 |
16.
|
References
|
344 |
17.
|
Index
|
359 |
