- Development and utilization of the United States gene bank collection. Of animals, that is: 1.15 million samples from 59,640 animals, representing 44 species of livestock, aquatic and insect genetic resources, 191 breeds and 369 subpopulations.
- Healthy cloned offspring derived from freeze-dried somatic cells. Another way to conserve in genebanks like the above, at least for mice.
- Genetic differentiation between coexisting wild and domestic Reindeer (Rangifer tarandus L. 1758) in Northern Eurasia. Now there’s better information to help decide how to conserve both in genebanks and outside, at least for reindeer.
- Dairying, diseases and the evolution of lactase persistence in Europe. Being able to digest milk didn’t help Neolithic people much. But not being able to digest milk during famines or plagues was really bad for them. Yeah but now we’re stuck with all that livestock.
- Signature of climate-induced changes in seafood species served in restaurants. Since 1880, the mean temperature preference of fish on Vancouver’s menus has increased by 3°C. Soon some will need genebanks, I guess. Or domestication.
- Win-win opportunities combining high yields with high multi-taxa biodiversity in tropical agroforestry. You don’t necessarily have to pay for higher vanilla yields with lower biodiversity. Good, because you can’t put everything in a genebank, I guess.
- Functional diversity of farmland bees across rural–urban landscapes in a tropical megacity. Oh look, another win-win!
- A review of management actions on insect pollinators on public lands in the United States. As in tropical megacities, removing invasives is an unalloyed good.
- Human Ecology: Special Issue on Dogs. Whether you’re a dog person or not, it’s hard to argue that any domesticated animal has engaged in a more diverse set of interactions with humans. Truly a win-win. But please, let’s not clone Fido.
What species belong in South Africa’s forages genebank?
It seems to have passed me by completely that Dr Marike Trytsman and colleagues at South Africa’s Agricultural Research Council have been systematically going through the country’s flora trying to figure out what needs to be in their national forages genebank.
I’m not sure I’ve ever seen such a thoroughgoing effort to prioritize species for ex situ conservation.
Animal domestication through the ages
Pretty good infographic on the history of animal domestication from the oddly named Visual Capitalist. References and a map would be good, but we mustn’t…ahem…look a gift horse in the mouth.
Brainfood: Wild scarlet runner beans, Wild coffee, Mexican vanilla, Hybrid barley, Zea genus, Wild maize gene, N-fixing xylem microbiota, Drone phenotyping, Wild tomato, Potato breeding, Wild potato, Wheat evaluation, Rice breeding returns
- The genomic signature of wild-to-crop introgression during the domestication of scarlet runner bean (Phaseolus coccineus L.). The wild Mexican genepool is helping to counteract the effects of the domestication bottleneck.
- Genetic variation in wild and cultivated Arabica coffee (Coffea arabica L.): Evolutionary origin, global distribution, and its effect on fungal disease incidence in Southwest Ethiopia. Domesticated disease-resistant cultivars are threatening the genetic integrity of the wild genepool. You win some, you lose some.
- Uncovering haplotype diversity in cultivated Mexican vanilla species. Plenty of evidence of past hybridization events in cultivated vanilla in Mexico. Maybe it can swap stories with scarlet runner bean.
- Six-rowed wild-growing barleys are hybrids of diverse origins. In the case of barley, the wild-cultivated hybrids even got a separate Latin binomial.
- Portrait of a genus: genome sequencing reveals evidence of adaptive variation in Zea. Lots of variation in interesting adaptive traits in the wild relatives of maize. Did they, or will they, make their way into the crop, I wonder?
- An adaptive teosinte mexicana introgression modulates phosphatidylcholine levels and is associated with maize flowering time. This one did.
- A highly conserved core bacterial microbiota with nitrogen-fixation capacity inhabits the xylem sap in maize plants. Its wild relatives are not the only wild organisms maize benefits from.
- Phenomic data-facilitated rust and senescence prediction in maize using machine learning algorithms. Drones and fancy maths can be used to predict and document southern rust infection in maize. Maybe in wild relatives too one day, who knows.
- A Solanum lycopersicoides reference genome facilitates insights into tomato specialized metabolism and immunity. A tomato wild relative has a gene for resistance to bacterial speck disease, so of course they had to sequence its genome.
- Genetic gains in potato breeding as measured by field testing of cultivars released during the last 200 years in the Nordic Region of Europe. Genetic gains for yield (measured in non-target environments) were not that great and contributed about half of productivity gains. Results for other traits were even worse, mainly because of stringent market demands. So no chance of using wild relatives I suppose.
- Genotypic Response and Selection of Potato Germplasm Under Heat Stress. Not so fast…
- Dataset of historic and modern bread and durum wheat cultivar performance under conventional and reduced tillage with full and reduced irrigation. I wonder to what extent wild relatives contributed to the differences.
- Assessing returns to research investments in rice varietal development: Evidence from the Philippines and Bangladesh. Net returns from collaboration in rice breeding between IRRI and national partners are still strong in the Philippines and Bangladesh, but declining, and faster in the former than the latter. Plenty of genes from wild relatives in IRRI lines of course. Maybe there could be more?
Documenting agricultural biodiversity everywhere
Nice to see a couple of examples of agrobiodiversity catalogues, albeit of very different kinds, available online.
The Catàleg de varietats locals de Catalunya (from that autonomous community of Spain’s Department d’Acció Climàtita, Alimentació i Agenda Rural) can be searched online by either cultivated species (hint: “mongueta” is Phaseolus vulgaris) or the “entitat” that is managing the landrace.
On the other hand, the Field Guide to the Cultivated Plants of the Philippines (Volume 1: Commonly cultivated species) from the Southeast Asian Regional Center for Graduate Study and Research in Agriculture (SEARCA) can be downloaded as a beautifully produced PDF.
And since I’m here, I might as well point to a nice infographic summarizing the cultivated Citrus family tree. I may have shared this (or something similar) before, but I’m hoping that if I keep doing so some of the details will eventually stick in my brain.