- A global overview of cassava genetic diversity. The African germplasm is different from the Latin American, but not by that much.
- Genetic variability in landraces populations and the risk to lose genetic variation. The example of landrace ‘Kyperounda’ and its implications for ex situ conservation. Better genetically to conserve landraces as sub-lines. But financially?
- Impact of merging commercial breeding lines on the genetic diversity of Landrace pigs. Above goes for pigs too.
- Selection and Molecular Characterization of Soybeans with High Oleic Acid from Plant Germplasm of Genebank. 3 accessions have interesting variants in the relevant gene.
- Origin and domestication of Cucurbitaceae crops: insights from phylogenies, genomics and archaeology. Lots of different paths to domestication, but all involve loss of flesh bitterness, one way or another.
- Changing Carrot Color: Insertions in DcMYB7 Alter the Regulation of Anthocyanin Biosynthesis and Modification. How the carrot lost its purple.
- A 3,000-year-old Egyptian emmer wheat genome reveals dispersal and domestication history. Most closely resembles modern material from Turkey, Oman and India.
- TeoNAM: A Nested Association Mapping Population for Domestication and Agronomic Trait Analysis in Maize. With added teosinte goodness.
- Adaptive phenotypic divergence in an annual grass differs across biotic contexts. The rhizosphere affects adaptation of teosinte along an altitudinal gradient. We’ll need a Nested Association Mapping Population for that too now, no doubt.
- Population genetics assessment model reveals priority protection of genetic resources in native pig breeds in China. Most breeds have low diversity; Tibetan pigs are an exception.
- A brief history of the forty-five years of the E’AppleBP apple breeding program in Brazil. 27 new varieties seems like pretty good going.
- Testing the Various Pathways Linking Forest Cover to Dietary Diversity in Tropical Landscapes. Sometimes there’s a direct pathway (e.g., consumption of forest food), sometimes an income pathway (income from forest products used to purchase food from markets), and sometimes an agroecological pathway (forests and trees sustaining farm production). And sometimes there isn’t.
- Evolutionary diversity is associated with wood productivity in Amazonian forests. “…greater phylogenetic diversity translates into higher levels of ecosystem function.” No word on its effect on diets.
- Anatomy and resilience of the global production ecosystem. Plenty of words on its effect on diets.
Nibbles: GB8, Aqueduct, Soviet tea, Tilapia virus, Quelites, NUS, Golden Thread, China Neolithic, Organic maize
- Virginia Gewin on GB8.
- Mapping water risks around the world.
- The decline and rise of Georgian tea.
- Virus hits tilapia. A lot of people could be hurt.
- Amaranthus in Mexico.
- Just one of many relatively neglected crops around the world that shouldn’t be.
- How wheat took over China. That was kinda underused at first too.
- Long webinar on organic maize breeding. Amaranthus next?
- The rise of fabric.
Brainfood: Cereal grains, Cerrado threats, Potato conservation, Maize rhizosphere, Coconut diversification, Lombard landraces, Lupinus evaluation, Genetic markers, Pathogen evolution, PAs & productivity, Agricultural expansion, Trade & obesity, ILRI genebank
- Large‐scale GWAS in sorghum reveals common genetic control of grain size among cereals. QTLs for grain size potential (rather than capacity to fill grains) identified in sorghum, turn out to be similar to other cereals.
- Linking global drivers of agricultural trade to on-the-ground impacts on biodiversity. Specific soy buyers with disproportionate impact on endemic and threatened cerrado species identified by fancy maths. Yes, you’re probably responsible for the plight of the giant anteater.
- Long-term conservation of potato genetic resources: Methods and status of conservation. Useful brief roundup.
- Impacts of Maize Domestication and Breeding on Rhizosphere Microbial Community Recruitment from a Nutrient Depleted Agricultural Soil. Hybrids changed the rhizosphere.
- Genome-wide diversity of northern South America cultivated Coconut (Cocus nucifera L.) uncovers diversification times and targets of domestication of coconut globally. Atlantic tall cultivar splits from Pacific cultivars approximately 5400 years ago, then Pacific Tall and Pacific Dwarf cultivars split from a shared common ancestor 1600 years ago.
- Forest pattern, not just amount, influences dietary quality in five African countries. Forests are good for you.
- Plant agro-biodiversity needs protection, study and promotion: results of research conducted in Lombardy region (Northern Italy). 78% of landraces lost in last 70-80 years, 72 left.
- Genomic prediction of grain yield in contrasting environments for white lupin genetic resources. It’s worth genotyping everything…
- Genetics without genes? The centrality of genetic markers in livestock genetics and genomics. …but genotyping-by-sequencing may not be necessary.
- Opportunities from the genetic diversity of the ILRI genebank forage germplasm collection. Genotyping-by-sequencing and morphology used to define mini-core subsets for important forages. So it is necessary for some things?
- The Green Revolution shaped the population structure of the rice pathogen Xanthomonas oryzae pv. oryzae. Strong selection leads to adaptation, fast. Well I never!
- Land productivity dynamics in and around protected areas globally from 1999 to 2013. Productivity increases are most common outside protected areas. But does that increase or decrease pressure on them? See below.
- Assessing the ecological vulnerability of forest landscape to agricultural frontier expansion in the Central Highlands of Vietnam. This is how you find out.
- Weight Gains from Trade in Foods: Evidence from Mexico. Food imports from US explain 20% of the increase in obesity in Mexican women.
The sweetest things
There’s been a lot of action on the cucurbit domestication front lately. Hot on the heels of a comprehensive Tansley review of all the crops in the family in New Phytologist ((Chomicki, G. , Schaefer, H. and Renner, S. S. (2019), Origin and domestication of Cucurbitaceae crops: insights from phylogenies, genomics and archaeology. New Phytol. doi:10.1111/nph.16015.)) now come two papers out of the Chinese Academy of Agricultural Sciences focusing on the melon and watermelon:
- Zhao, G., Lian, Q., Zhang, Z. et al. A comprehensive genome variation map of melon identifies multiple domestication events and loci influencing agronomic traits. Nat Genet 51, 1607–1615 (2019) doi:10.1038/s41588-019-0522-8.
- Guo, S., Zhao, S., Sun, H. et al. Resequencing of 414 cultivated and wild watermelon accessions identifies selection for fruit quality traits. Nat Genet 51, 1616–1623 (2019) doi:10.1038/s41588-019-0518-4.
There are press releases on each of these, of course. But the more interesting take is provided by some IPK researchers ((Jayakodi, M., Schreiber, M. & Mascher, M. Sweet genes in melon and watermelon. Nat Genet 51, 1572–1573 (2019) doi:10.1038/s41588-019-0529-1.)), who mash up the two studies. ((Here’s another mash-up.)) And provide a nice graphic to summarize the whole thing.
The bottom line(s)? The two different subspecies of melon acquired sweet flesh through different mutations, independently but probably both in India; there was a third domestication event in Africa, but the authors had too little material at hand to say much about this. Melon and watermelon lost their bitterness through convergent evolution, and the latter has benefitted from introgression from two wild relatives, one of which was separately domesticated for its seeds.
Nibbles: Root & tuber breeding, Potato fun, Melon domestication, Maize conservation, Millet diversification, Business as usual
- A backyard breeder evaluates USDA’s potato accessions. Among other things.
- The Onion roasts potatoes.
- How melons got sweet.
- Mexican Senate considers in situ/on farm conservation areas for maize.
- Millets for climate change resilience in India.
- Business for biodiversity. Yeah, right.