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currently prevailing. Random changes (mutations), natural selection, and reproduction
(replication) work together to achieve this. Sexual reproduction also allows new gene
combinations in the offspring through recombination of the paternal and maternal genome.
Depending on the environment, a mutation can thus be beneficial or detrimental or insig
nificant (neutral). Although this makes the evolution of genetic material a very complex
process in populations, it is now possible to determine how these representative sequences
change over time and how different they are in different populations by systematic
sequence comparison of typical sequences for a population. One can then calculate from
many such sequence comparisons (see Sects. 10.3 and 10.4) how different different popu
lations are (one often compares species) and can then calculate back how the precursor
populations looked (also extinct species).
This is all surprisingly difficult when looked at in detail, e.g. which sequences are rep
resentative of the population? Answer: The most frequent sequences in the population. So
ideally you have to sequence many individuals, like in the 1000 genomes project for the
human genome. However, when do I have a new species? This is not a problem for verte
brates and mammals, but it is not at all easy to determine with certainty for all other living
organisms. Originally, individuals were classified morphologically (differing in appear
ance) and then simply called species. Later, a species was defined as a sexually fertile
reproductive community between individuals in a population. This does not work for bac
teria. Here, genetic exchange is complex with many transitions and reproduction is usually
asexual, so that a three percent difference in the genome is often pragmatically defined as
a new species. One also has to look carefully at the resulting phylogenetic trees in order
not to make any mistakes, for example whether one can determine an original species
(“root”) or whether it is better not to do so because of the unclear data situation. Another
example error in reconstruction is the tree-building error (long branch attraction), since
systematic errors can often occur, in particular distantly related species are wrongly con
sidered closely related or closely related species are wrongly considered unrelated, which
arises when sequences of different lengths are compared or when a single sequence is
quite long and the taxa have a different number of mutations.
10.1