Mind the conservation gap

In the interest of completeness, I feel it incumbent upon me to complement the post on gap analysis for crop diversity conservation that I put up a few days ago with a couple of additional links.

The Crop Trust and FAO elearning Academy have collaborated on a course on the Global Crop Conservation Strategies that includes a lesson on “Crop coverage assessments and gap analysis.”

And our friends at the Alliance of Bioversity & CIAT have also made available a “Curriculum of an online lesson for gap analysis.”

So there’s really no excuse for not doing your own gap analysis, is there? And add to the storied history of the field.

Character study

Do you work in a national genebanks? If so, you might want to take a survey on your “molecular characterisation capacity, infrastructure, policy environment, and interest in future DSI collaboration with CGIAR.”

A brief history of gap analysis for crop diversity conservation

Many thanks to long-time friend-of-the-blog Dr Colin Khoury for this latest contribution.

Conservation gap analysis using Geographic Information System (GIS) tools relies on several sources of biological and environmental data, including in situ species occurrences and climatic and other environmental variables used to conduct species distribution modeling, as well as passport data from ex situ collections. While species distribution modeling and associated methods had been in development since at least the 1970s (see Rebelo, 1994 and Booth et al., 2013), the widespread use of these tools was not possible until such biological and environmental data were more easily and widely accessible, for example through GBIF, WorldClim, and Genesys.

Genebank scientists, often in collaboration with academic researchers, began to apply available GIS-based tools to PGRFA conservation around the turn of the century, proceeding to develop new methods, software, and datasets (for early examples, see Guarino, 1995; Greene and Guarino, 1999; Guarino et al., 2002). Global climate datasets were compiled at relatively high spatial resolution (e.g., Hijmans et al., 2005), providing key inputs for species distribution modeling. Current distribution models for plant genetic resources began to be calculated, for example for wild relatives of potatoes and peanuts, while future distributions under climate change also began to be modeled, for example for wild peanuts, potatoes, and cowpeas. Field collecting was informed through these tools, for example for wild clover and wild chile pepper expeditions.

The focus on wild relatives of food and agricultural crops was not haphazard. These species were receiving increasing conservation attention at the time in recognition of their value as genetic resources for crop breeding, and because many wild relatives were known to be threatened in their natural habitats and were underrepresented in ex situ repositories. International conservation targets for crop wild relatives had been set at the Convention on Biological Diversity (CBD) (for 2011 to 2020 and again for 2020 to 2030) and in the United Nations Sustainable Development Goals (SDGs) (for 2015 to 2030). At the same time, species distribution modeling methods had primarily been developed for wild species, i.e. taxa whose distributions are mainly driven by climatic, edaphic, and other environmental factors, rather than human preferences (which are more difficult to model), therefore the application of these methods to crop wild relatives was relatively straightforward and a logical starting point for the agricultural research community.

Programs such as DIVA-GIS and FloraMap were created to make the methods more accessible to researchers and practitioners without extensive GIS experience and computing power. Such efforts continue, for example by CAPFITOGEN.

Through an international genebank initiative called the Global Public Goods Project II, run from 2007-2010, the distributions of the wild relatives of ten CGIAR mandate crops were mapped, with priorities for further collecting for ex situ conservation identified. A major milestone of that project was the publication of a standardized, replicable gap analysis methodology for the ex situ conservation of crop wild relatives, which made use of herbarium and other biodiversity observations acquired through GBIF and other sources, as well as genebank passport data, and which embraced recent advancements in species distribution modeling methods.

Continue reading “A brief history of gap analysis for crop diversity conservation”

Playing around with wild potatoes

Journey through 1946’s South America to find and collect wild potato plants, which might hold the key to defeat the blight affecting British crops.

Choose your route, solve puzzles, and learn more about the world of potato biodiversity. But be careful not to run out of resources or you’ll have to cut your expedition short!

That’s all the introduction you get to a new online game from Abertay University and the James Hutton Institute, but it’s clearly inspired by Jack Hawkes’ famous potato collecting expeditions to South America. The resulting Empire Potato Collection, now called the Commonwealth Potato Collection, is still maintained at the Hutton. Our friend Mike Jackson has blogged very comprehensively about it, and also about his own efforts following in the footsteps of Prof. Hawkes.

Let’s see what Mike thinks about the game. I found it a little tricky to get into, though mildly entertaining once I did. But I never collected wild potatoes.

Brainfood: Animal genetic resources