分子生物学

In the Japanese rhinoceros beetle Trypoxylus dichotomus, gene function studies have relied mainly on systemic larval RNA interference (RNAi), as gain-of-function techniques remain underdeveloped and germline transgenesis is impractical given the species’ approximately one-year generation time. In addition, because larval RNAi is systemic, it has been difficult to analyze the function of lethal genes. Here, we present a simple and efficient protocol for the direct introduction of exogenous DNA into T. dichotomus larvae via in vivo electroporation. This protocol includes optimized procedures for adult breeding and egg collection, as well as a rigorously parameterized electroporation technique that delivers a piggyBac transposon vector into region-specific larval tissues. Within one day after electroporation, treated larvae exhibit mosaic expression of a reporter gene, enabling rapid tissue-specific functional analysis without the need to establish stable germline transgenic lines. Moreover, the key promoter used in this system (T. dichotomus actinA3 promoter) is effective across diverse insect species, indicating that the method can be readily adapted to other non-model insects. Overall, this electroporation-based approach provides a valuable gain-of-function tool for T. dichotomus and potentially many other insect species.

Erwinia persicina is a gram-negative bacterium that causes diseases in plants. Recently, E. persicina BST187 was shown to exhibit broad-spectrum antibacterial activity due to its inhibitory effects on bacterial acetyl-CoA carboxylase, demonstrating promising potential as a biological control agent. However, the lack of suitable genetic manipulation techniques limits its exploitation and industrial application. Here, we developed an efficient transformation system for E. persicina. Using pET28a as the starting vector, the expression cassette of the red fluorescent protein–encoding gene with the strong promoter J23119 was constructed and transformed into BST187 competent cells to verify the overexpression system. Moreover, suicide plasmid–mediated genome editing systems was developed, and lacZ was knocked out of BST187 genome by parental conjugation transfer using the recombinant suicide vector pKNOCK-sacB-km-lacZ. Therefore, both the transformation and suicide plasmid–mediated genome editing system will greatly facilitate genetic manipulations in E. persicina and promote its development and application.

Key features

• Our studies establish a genetic manipulation system for Erwinia persicina, providing a versatile tool for studying the gene function of non-model microorganisms.

• Requires approximately 6–10 days to complete modification of a chromosome locus.

Graphical overview

Magnaporthe oryzae is a filamentous fungus responsible for the detrimental rice blast disease afflicting rice crops worldwide. For years, M. oryzae has served as an excellent model organism to study plant pathogen interactions due to its sequenced genome, its amenability to functional genetics, and its capacity to be tracked in laboratory settings. As such, techniques to genetically manipulate M. oryzae for gene deletion range from genome editing via CRISPR-Cas9 to gene replacement through homologous recombination. This protocol focuses on detailing how to perform gene replacement in the model organism, M. oryzae, through a split marker method. This technique relies on replacing the open reading frame of a gene of interest with a gene conferring resistance to a specific selectable chemical, disrupting the transcription of the gene of interest and generating a knockout mutant M. oryzae strain.

Key features

• Comprehensive overview of primer design, PEG-mediated protoplast transformation, and fungal DNA extraction for screening.

Phytophthora sojae is a model species for the study of plant pathogenic oomycetes. The initial research on gene function using Phytophthora was mainly based on gene silencing technology. Recently, the CRISPR/Cas9-mediated genome editing technology was successfully established in P. sojae and widely used in oomycetes. In this protocol, we describe the operating procedures for the use of CRISPR/Cas9-based genome editing technology and PEG-mediated stable transformation of P. sojae protoplasts. Two plasmids were co-transformed into P. sojae: pYF515 expressing Cas9 and the single guide RNA, and the homologous replacement vector of the candidate gene. Finally, the ORF of candidate gene were replaced with the ORF of the entire hygromycin B phosphotransferase gene (HPH), to achieve precise knockout.

Ascidian embryos are powerful models for functional genomics, in particular, due to the ease of generating a large number of transgenic embryos by electroporation. In addition, the small size of their genome makes them an attractive model for studying cis-regulatory elements that control gene expression during embryonic development. Here, I describe the adaptation of the seminal method developed 25 years ago in Ciona robusta for en masse DNA electroporation for in vivo transcription to additional species belonging to three genera. It is likely that similar optimizations would make electroporation successful in other ascidian species, where in vitro fertilization can be performed on a large number of eggs.

Ralstonia solanacearum is a devastating soil-borne bacterial pathogen that causes disease in multiple host plants worldwide. Typical assays to measure virulence of R. solanacearum in laboratory conditions rely on soil-drenching inoculation followed by observation and scoring of disease symptoms. Here, we describe a novel inoculation protocol to analyze the replication of R. solanacearum upon infiltration into the leaves of Nicotiana benthamiana, in which gene expression has been altered using Agrobacterium tumefaciens. The protocol includes five major steps: 1) growth of N. benthamiana plants; 2) infiltration of A. tumefaciens; 3) R. solanacearum inoculation; 4) sample collection and bacterial quantitation; 5) data analysis and representation. The transient gene expression or gene silencing prior to R. solanacearum inoculation provides a straightforward way to perform genetic analysis of plant functions involved in the interaction between pathogen and host, using the appropriate combination of A. tumefaciens and R. solanacearum strains, with high sensitivity and accuracy provided by the quantitation of bacterial numbers in plant tissues.

Sweet basil (Ocimum basilicum) is a popular herb with high economic value and is currently threatened by a severe oomycete disease. An efficient transformation method is a prerequisite for gene functional analysis to accelerate molecular breeding and deploy effective disease management strategies, and breeding through genetic engineering. Here we present a detailed protocol for a highly efficient Agrobacterium tumefaciens-mediated transformation method for sweet basil, which was established based on a previously reported method by other researchers, with modifications on several aspects, including growth of sweet basil, age of plants used for explants, preparation and concentration of Agrobacteria. This protocol allows researchers in academia and agroindustry to generate transgenic sweet basil plants in an easy, quick and highly reproducible manner. In addition, this protocol may be applicable to transform other species within the genus Ocimum.