Nowadays
genomics is pervading many research fields in biology, and
conservation biology is not an exception anymore. The Giant panda was
perhaps the first organism selected for sequencing in which the
primary reason was its status as an endangered species. Since then,
other species have been selected for sequencing, in an effort to
contribute to their conservation. To name a few: the Californian
condor, the
Tiger, Tasmanian devil and
the Iberian lynx, are also entering the genomic era. Our group is
contributing to the efforts of sequencing and analyzing the Iberian
Lynx genome, an emblematic predator of our peninsula which has the
dubious honor to be the most endangered feline species on the planet.
With a population below 400, a fragmented and restricted distribution
area and a dangerously low level of genetic diversity, its situation
is rather critical. Two years ago a consortium of Spanish research groups joined forces to sequence this species' genome.
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| "Candiles" the sequenced Iberian Lynx male |
I
have been asked many times if this effort will definitely save the
species, or even whether the money would not be better invested in
other efforts. How can a genome help in saving an endangered
species?, are we feeding unreasonable expectations on the possible
role of genomics in species conservation? Although only time will
tell whether such efforts will pay off, I consider that genomics can
certainly provide a new, very useful angle to species conservation.
In any case, genomics should be considered just as another tool
towards species conservation, rather than as the definitive solution.
Species are endangered because of various causes, mostly territory
loss and degradation, overexploitation, and alteration of their
ecological networks. It is obvious that the main focus should be
given to fight the causes that triggered population drops and create
the necessary conditions for the populations to recover safely. As a
powerful tool to understand a species' biology, and as a way to
investigate past and current population dynamics, the availability of
a genome can greatly help in understanding some of the factors that
may have been decisive in population decline. Having a reference
genome opens the door for a closer genetic monitoring of wild
populations, not only because it enables the selection of new marker
genes than can be sampled in many individuals but also because it
paves the way for obtaining whole genome-level population data by
re-sequencing strategies. Indeed, our project includes already
re-sequencing of additional individuals from the main fragmented
territories occupied by the species.
Having
such kind of data is key to understand gene flow among the different
populations, since it will provide a better picture of the genetic
pools of the different populations. This will help to better plan crosses among captive individuals -mainly those
with permanent injuries that cannot be successfully released to the
wild- and future releases of their progeny. This will have a direct
impact in the case of the Iberian lynx, where high levels of
inbreeding and low genetic diversity exposes fragmented populations
to a higher rate of diseases with a genetic basis (particularly a
renal disease), and a reduced potential to overcome potential
infectious diseases. A better knowledge of the genetic pool of both
wild and captive populations will undoubtedly help in guiding
strategies to help them recover. In addition individuals and their
territories could be tracked from materials such as faeces or hairs. Other applications may be more
specific for a particular endangered species, for instance in the
tasmanian devil, genomics has been used to track a transmissible
cancer that causes a facial tumor disease that is transmitted by
biting.
Other applications of conservation genomics that go beyond the sequencing of the endangered species itself, refer to the monitoring, using similar genomics tools, of important pathogens or symbionts of endangered species. Of course all these efforts will only be of little help if the causes that drove their decline are still around. Thus there is a growing number of promising possible applications of genomics to the conservation of endangered species, some of them already at work. I expect this field to grow fast in the coming years, as a concerned scientist I am proud that my particular corner of expertise can contribute to the noble cause of helping to keep the biodiversity of our planet.
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| Tasmanian devil with transmissible facial tumor |
Other applications of conservation genomics that go beyond the sequencing of the endangered species itself, refer to the monitoring, using similar genomics tools, of important pathogens or symbionts of endangered species. Of course all these efforts will only be of little help if the causes that drove their decline are still around. Thus there is a growing number of promising possible applications of genomics to the conservation of endangered species, some of them already at work. I expect this field to grow fast in the coming years, as a concerned scientist I am proud that my particular corner of expertise can contribute to the noble cause of helping to keep the biodiversity of our planet.
