Susanne Kjemtrup

Environmental versus geographical effects on genomic variation in wild soybean (Glycine soja) across its native range in northeast Asia

Abstract A fundamental goal in evolutionary biology is to understand how various evolutionary factors interact to affect the population structure of diverse species, especially those of ecological and/or agricultural importance such as wild soybean (Glycine soja). G. soja, from which domesticated soybeans (Glycine max) were derived, is widely distributed throughout diverse habitats in East Asia (Russia, Japan, Korea, and China). Here, we utilize over 39,000 single nucleotide polymorphisms genotyped in 99 ecotypes of wild soybean sampled across their native geographic range in northeast Asia, to understand population structure and the relative contribution of environment versus geography to population differentiation in this species. A STRUCTURE analysis identified four genetic groups that largely corresponded to the geographic regions of central China, northern China, Korea, and Japan, with high levels of admixture between genetic groups. A canonical correlation and redundancy analysis showed that environmental factors contributed 23.6% to population differentiation, much more than that for geographic factors (6.6%). Precipitation variables largely explained divergence of the groups along longitudinal axes, whereas temperature variables contributed more to latitudinal divergence. This study provides a foundation for further understanding of the genetic basis of climatic adaptation in this ecologically and agriculturally important species.

A VIGS screen identifies immunity in the Arabidopsis Pla-1 accession to viruses in two different genera of the Geminiviridae

Summary Geminiviruses are DNA viruses that cause severe crop losses in different parts of the world, and there is a need for genetic sources of resistance to help combat them. Arabidopsis has been used as a source for virus‐resistant genes that derive from alterations in essential host factors. We used a virus‐induced gene silencing (VIGS) vector derived from the geminivirus Cabbage leaf curl virus (CaLCuV) to assess natural variation in virus–host interactions in 190 Arabidopsis accessions. Silencing of CH‐42, encoding a protein needed to make chlorophyll, was used as a visible marker to discriminate asymptomatic accessions from those showing resistance. There was a wide range in symptom severity and extent of silencing in different accessions, but two correlations could be made. Lines with severe symptoms uniformly lacked extensive VIGS, and lines that showed attenuated symptoms over time (recovery) showed a concomitant increase in the extent of VIGS. One accession, Pla‐1, lacked both symptoms and silencing, and was immune to wild‐type infectious clones corresponding to CaLCuV or Beet curly top virus (BCTV), which are classified in different genera in the Geminiviridae. It also showed resistance to the agronomically important Tomato yellow leaf curl virus (TYLCV). Quantitative trait locus mapping of a Pla‐1 X Col‐0 F2 population was used to detect a major peak on chromosome 1, which is designated gip‐1 (geminivirus immunity Pla‐1‐1). The recessive nature of resistance to CaLCuV and the lack of obvious candidate genes near the gip‐1 locus suggest that a novel resistance gene(s) confers immunity.

Persistent Virus-Induced Gene Silencing in Asymptomatic Accessions of Arabidopsis

Coupled with the advantages afforded by the model plant Arabidopsis, virus-induced gene silencing (VIGS) offers a rapid means to assess gene function. The geminivirus vector based on Cabbage leaf curl virus described here has the benefits of small insert size and persistent silencing of the target gene through the life cycle of the plant. Here, we show that genetic variation in the vast collection of Arabidopsis accessions can be leveraged to ameliorate viral symptomology that accompanies the VIGS procedure. The plasticity of phenotypes under different day lengths or temperature conditions can be exploited to achieve maximum silencing efficacy in either vegetative or inflorescence tissue, according to the question being asked. Protocols and vectors for Agro-infiltration of primary leaves, subapical pricking in older plants, and microprojectile bombardment are described.