IntroductionPopulation genetic stud

Introduction
Population genetic studies based on molecular markers indicate
how Quaternary climate oscillations have influenced the extant
genetic structure of plants (Lascoux
et al
., 2004). Similarly, the
establishment of large-scale pollen and macrofossil databanks
and the comparative analyses of genetic and fossil data (Brewer
et al
., 2002; Taberlet & Cheddadi, 2002; Petit
et al
., 2003) have
considerably improved our knowledge of the distribution of
plants since the last glaciation and has led to a better understanding
of their ecological setting (Bennett, 1997; Elenga
et al
.,
2000; Litt
et al
., 2003). A more direct and largely complementary
approach to study past population processes would
be provided by palaeogenetics (i.e. the study of ancient DNA
(aDNA)). Ancient DNA research deals with DNA molecules
that have been subjected to post mortem degradation primarily
through hydrolysis and oxidation. In plants, these DNA
molecules can be found in tissues of extant organisms, such as
wood or sclerenchymatic tissue of fruits or seeds, in herbarium
specimens, in various types of fossilized plant remains, in feces
as secondary components or even adsorbed to sediments after
leakage from their original cellular source.
In principle, insights into the evolutionary history of plant
populations can be obtained by (1) relying on direct evidence
from the fossil record, (2) studying the current genetic structure
of living organisms, (3) genetically analysing germinated seeds
or spores buried in the soil, or (4) directly identifying species
and genotypes through the analysis of aDNA (palaeogenetics).
Plant palaeontological research is often limited by taxonomic
resolution because fossil remains, such as wood or pollen, can