State Key Laboratory of Plant Molecular Genetics

Rhizobium infects host legumes to elicit new plant organs, nodules where dinitrogen is fixed as ammonia that can be directly utilized by plants. The nodulation factor (NF) produced by Rhizobium is one of the determinant signals for rhizobial infection and nodule development. Recently, it was found to suppress the innate immunity on host and nonhost plants as well as its analogs, chitins. Therefore, NF can be recognized as a microbe/pathogen-associated molecular pattern (M/PAMP) like chitin to induce the M/PAMP triggered susceptibility (M/PTS) of host plants to rhizobia. Whether the NF signaling pathway is directly associated with the innate immunity is not clear till now. In fact, other MAMPs such as lipopolysaccharide (LPS), exopolysaccharide (EPS) and cyclic-β-glucan, together with type III secretion system (T3SS) effectors are also required for rhizobial infection or survival in leguminous nodule cells. Interestingly, most of them play similarly negative roles in the innate immunity of host plants, though their signaling is not completely elucidated. Taken together, we believe that the local immunosuppression on host plants induced by Rhizobium is essential for the establishment of their symbiosis.

Abstract Broomcorn millet ( Panicum miliaceum L.) was domesticated in northern China at least 7,000 years ago and was subsequentially adopted as a cereal in many areas throughout Eurasia. One such locale is Areni-1 an archaeological cave site in Southern Armenia, a region that has an important history in crop domestication. The rich botanical material found at Areni-1 includes grains identified by morphology as broomcorn millet that were 14 C dated to the medieval era (873 ± 36 CE and 1118 ± 35 CE). To retrace the demographic history of these broomcorn millet samples, we used ancient DNA extraction and hybridization capture enrichment to sequence and assemble three chloroplast genomes from the Areni-1 grains and then compared these sequences to 50 modern chloroplast genomes. Overall, the chloroplast genomes contained a low amount of diversity and little inference on broomcorn demography could be made. However, in a phylogeny the chloroplast genomes separated into two clades with strong bootstrap support, similar to what has been reported for nuclear DNA from broomcorn millet. In a haplotype network, the chloroplast genomes of two accessions of wild (undomesticated) broomcorn millet contained a relatively large number of variants, 11 SNPs. These SNPs were not present in the domesticated varieties, suggesting these wild accessions may not be directly related to the lineages that underwent domestication or that broomcorn millet may have undergone a domestication bottleneck resulting in lost diversity in the chloroplast genome. These results demonstrate that broomcorn millet from archaeological sites can preserve DNA for at least 1000 years and serve as a genetic resource to study the domestication of this cereal crop.

An insecticidal crystal protein gene of Bacillus thuringiensis was transferred into cabbage genome with the method of Agrobacterium infection. Cotyledons with petioles as explants were cocultivated with Agrobacterial suspension. Calli generated at the basis of petiole were subjected to selection on the MS medium containing 15-30 mg/L kanamycin (Km). About 5% explants produced calli growing continuously on the selective medium. Green shoots appeared on these calli when they were transplanted onto medium with Km and 6-BA for plant differentiation. The shoots were separated and cultivated on medium with kanamycin. About 80% shoots were rooted. Non-transformed control calli could not give normal shoots and roots and brownized and died gradually. Larvae of Pieris rapae showed poisonous symptoms: growth inhibition and mortality when fed with the leaf of the transgenic plants. About 80% of regenerated plants showed positive hybridization bands when their DNA were probed with crystal protein sequence of Bacillus thuringiensis. Mendel's segregation was observed among plants grown up from the seeds of transgenic cabbage plants both in kanamycin resistance and insecticidal activity against Pieris rapae larvae.