Publications

Rapid and accurate diagnostic tests make an important contribution to programmes to monitor and eradicate infectious diseases that impact animal and plant health. Using foot-and-mouth disease (FMD) and sudden oak death as examples, this review outlines recent progress to develop new field tools for detection of the infectious agents that cause high-impact livestock and plant diseases. The principal driver for this work is to develop tools that can be used locally to assist in decision making. Advances in this area have developed simple-to-use lateral-flow devices for the detection of FMD virus and the genus Phytophthora (including Phytophthora ramorum, the causal agent of sudden oak death and the related pathogen P. kernoviae), as well as new hardware platforms to allow PCR testing for these agents by non-specialists in the field. Although developed for different diseases, the user requirements for rapid diagnostic tools for FMD and sudden oak death share many similarities. Using generic solutions to these challenging problems, it is now possible to imagine a new paradigm for how the collection and testing of samples to monitor the spread of important livestock and plant diseases might be achieved.

Background: The Asian tiger mosquito, Aedes albopictus (Skuse), is a vector of several arboviruses including dengue and chikungunya. This highly invasive species originating from Southeast Asia has travelled the world in the last 30 years and is now established in Europe, North and South America, Africa, the Middle East and the Caribbean. In the absence of vaccine or antiviral drugs, efficient mosquito control strategies are crucial. Conventional control methods have so far failed to control Ae. albopictus adequately. Methodology/Principal Findings: Germline transformation of Aedes albopictus was achieved by micro-injection of embryos with a piggyBac-based transgene carrying a 3xP3-ECFP marker and an attP site, combined with piggyBac transposase mRNA and piggyBac helper plasmid. Five independent transgenic lines were established, corresponding to an estimated transformation efficiency of 2-3%. Three lines were re-injected with a second-phase plasmid carrying an attB site and a 3xP3-DsRed2 marker, combined with PhiC31 integrase mRNA. Successful site-specific integration was observed in all three lines with an estimated transformation efficiency of 2-6%. Conclusions/Significance: Both piggybac-and site-specific PhiC31-mediated germline transformation of Aedes albopictus were successfully achieved. This is the first report of Ae. albopictus germline transformation and engineering, a key step towards studying and controlling this species using novel molecular techniques and genetic control strategies.

Background: Combinatorial RNA interference (co-RNAi) is a valuable tool for highly effective gene suppression of single and multiple-genes targets, and can be used to prevent the escape of mutation-prone transcripts. There are currently three main approaches used to achieve co-RNAi in animal cells; multiple promoter/shRNA cassettes, long hairpin RNAs (lhRNA) and miRNA-embedded shRNAs, however, the relative effectiveness of each is not known. The current study directly compares the ability of each co-RNAi method to deliver pre-validated siRNA molecules to the same gene targets. Results: Double-shRNA expression vectors were generated for each co-RNAi platform and their ability to suppress both single and double-gene reporter targets were compared. The most reliable and effective gene silencing was achieved from the multiple promoter/shRNA approach, as this method induced additive suppression of single-gene targets and equally effective knockdown of double-gene targets. Although both lhRNA and microRNA-embedded strategies provided efficient gene knockdown, suppression levels were inconsistent and activity varied greatly for different siRNAs tested. Furthermore, it appeared that not only the position of siRNAs within these multi-shRNA constructs impacted upon silencing activity, but also local properties of each individual molecule. In addition, it was also found that the insertion of up to five promoter/shRNA cassettes into a single construct did not negatively affect the efficacy of each individual shRNA. Conclusions: By directly comparing the ability of shRNAs delivered from different co-RNA platforms to initiate knockdown of the same gene targets, we found that multiple U6/shRNA cassettes offered the most reliable and predictable suppression of both single and multiple-gene targets. These results highlight some important strengths and pitfalls of the currently used methods for multiple shRNA delivery, and provide valuable insights for the design and application of reliable co-RNAi

Salmonella enterica serovar Typhimurium is an animal and zoonotic pathogen of worldwide importance. Intestinal colonization, induction of enteritis and systemic translocation by this bacterium requires type III protein secretion. Strategies that target this process have the potential to control infection, pathology and transmission. We defined the global transcriptional response of S. Typhimurium to INP0403, a member of a family of salicylidene acylhydrazides that inhibit type III secretion (T3S). INP0403 treatment was associated with reduced transcription of genes involved in T3S, but also increased transcription of genes associated with iron acquisition. We show that INP0403 restricts iron availability to Salmonella, and that inhibition of T3S system-1 by INP0403 is, at least in part, reversible by exogenous iron and independent of the iron response regulator Fur.