Plant diseases and insect pests are serious threat to the growth and yield of oilseed rape. In this study, a binary vector carrying sporamin and chitinase PjChi-1 genes in tandem was introduced into Brassica napus cv. ZS 758 via Agrobacterium tumefaciens for dual resistance against disease and insect attack. Thirty-two regenerated plantlets exhibiting hygromycin resistance were selected following Agrobacterium-mediated transformation of 600 leaf petiole explants. Of these, 27 transformants were confirmed to carry the two transgenes as detected by polymerase chain reaction (PCR) with 4.5% transformation efficiency. Eight plantlets were randomly selected for further confirmation by Southern and northern blot hybridization analyses. Four plants carried single copy of the transgenes, while the remaining four plants carried either two or three copies of the transgenes. Moreover, expression of the sporamin transgene was detected by northern blot hybridization in transgenic lines, but not in wild-type plants. These eight T 0 plants were grown in vitro, and inoculated with the Lepidoptera larvae of Plutella xylostella and with spores of the fungal pathogen of Sclerotinia sclerotiorum. Transgenic plants exhibited high levels of resistance to P. xylostella and S. sclerotiorum when compared to untransformed wild-type plants. Genetic analysis of T 1 progeny confirmed Mendelian segregation of the introduced genes. Therefore, these transgenic lines demonstrate a promising potential for variety development of oilseed rape lines with enhanced resistance against both P. xylostella and S. sclerotiorum.
2019) Research on development characteristics and failure mechanism of land subsidence and ground fissure in Xi'an, monitored by using time-series SAR interferometry,
Summary
New genes often drive the evolution of gene interaction networks. In Brassica napus, the widely used genic male sterile breeding system 7365ABC is controlled by two young genes, Bnams4b and BnaMs3. However, the interaction mechanism of these two young genes remains unclear.
Here, we confirmed that Bnams4b interacts with the nuclear localised E3 ligase BRUTUS (BTS). Ectopic expression of AtBRUTUS (AtBTS) and comparison between Bnams4b‐transgenic Arabidopsis and bts mutants suggested that Bnams4b may drive translocation of BTS to cause various toxic defects.
BnaMs3 gained an exclusive interaction with the plastid outer‐membrane translocon Toc33 compared with Bnams3 and AtTic40, and specifically compensated for the toxic effects of Bnams4b. Heat shock treatment also rescued the sterile phenotype, and high temperature suppressed the interaction between Bnams4b and BTS in yeast. Furthermore, the ubiquitin system and TOC (translocon at the outer envelope membrane of chloroplasts) component accumulation were affected in Bnams4b‐transgenic Arabidopsis plants.
Taken together, these results indicate that new chimeric Bnams4b carries BTS from nucleus to chloroplast, which may disrupt the normal ubiquitin–proteasome system to cause toxic effects, and these defects can be compensated by BnaMs3−Toc33 interaction or environmental heat shock. It reveals a scenario in which two population‐specific coevolved young genes reshape a novel interaction network in plants.
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