Reconstructing a plant biodiversity tree
Understanding the mechanisms that drive biodiversity and species richness is critical to plant conservation in the face of climate change. However, these mechanisms remain one of biology's great unsolved mysteries.
In the face of modern climate change, conservation depends on an
understanding of what influences regional and global plant diversity.
The plant biodiversity observed today is at least partially due to
prehistoric climate patterns that influenced evolutionary history. And
yet, questions remain regarding the large-scale biodiversity
ramifications of ongoing climate shifts.
EU-funded researchers recognised that molecular and taxonomic
relationships (phylogenies), compared with contemporary species
distributions, could answer some questions. Working on the project
'Plant biodiversity of China in a changing world: Evolution and
conservation' (PDIVCHINA), researchers focused on massive datasets for
the Quercus and Rhododendron genera.
PDIVCHINA's results suggest prehistoric factors affected modern
Quercus and Rhododendron distribution. In particular, where species'
ranges decreased, evidence of prehistoric influence increased.
Similarly, the high diversity of Rhododendron species can be attributed
in part to serious climate shifts in the late Eocene and early
Oligocene.
Additionally, PDIVCHINA developed extensive phylogenies for woody
plant families, along with genus-level phylogenies of 70 families. In
analysing these evolutionary relationships, PDIVCHINA found explicit
results. South-eastern China hosts the oldest species; moving northward,
there is a trend towards younger species.
PDIVCHINA also mapped the species distribution of 7 680 woody
plants. With these maps in hand, researchers investigated how plants
would respond to four distinct climate change scenarios. Intensive
heterogeneity is most likely, and the Tibetan Plateau is likely to
experience an advent of woody species, while southern China would lose
these. Interestingly, PDIVCHINA predicted that phylogenetic diversity
could be conserved at the family level, but species-level loses are to
be expected.
Addressing contemporary conservation challenges, the researchers
mapped China's biodiversity hotspots. They also assessed the relative
phylogenetic diversity of China's endangered woody plants. PDIVCHINA
then evaluated the socioeconomic and ecosystem services associated with
woody plants within and outside the nation's natural reserves. The
research team concluded that forest conservation is linked to rural
poverty, and must therefore be included in rural development strategies.
PDIVCHINA has provided the world a refined picture of how climate
shifts may affect plant biodiversity and the behaviour of humans who
live near endangered plant species. Such comprehensive awareness is
essential for scientists and policymakers tasked with conserving China's
natural heritage.
published: 2015-02-19