Injection-mediated transposon transgenesis in Xenopus tropicalis and the identification of integration sites by modified extension primer tag selection (EPTS) linker-mediated PCR

The generation of transgenic lines is vital to many genetic strategies and provides useful reagents for cell labeling and lineage-tracing experiments. Transposon-based systems offer simple, yet robust, platforms for transgenesis in the frog. Here, we provide a protocol for a microinjection-based transposon transgenesis method using a 'natural breeding' strategy for the collection of Xenopus tropicalis embryos. This method uses co-injection of a plasmid containing a transposon substrate together with synthetic mRNA encoding the transposase to achieve efficient integration of the transgene in the frog genome. We also describe a modified extension primer tag selection linker-mediated PCR technique to identify transposon integration sites within the host genome. This cloning strategy allows rapid identification of genomic sequences flanking the integration sites and multiple independently segregating transposon integration events in a single tadpole can be cloned simultaneously.     

Manipulating the <Emphasis Type="Italic">Xenopus</Emphasis>genome with transposable elements

The study of amphibian embryogenesis has provided important insight into the mechanisms of vertebrate development. The frog Xenopus laevis has been an important model of vertebrate cell biology and development for many decades. Genetic studies in this organism are not practical because of the tetraploid nature of the genome and the long generation time of this species. Recently, a closely related frog, namely Xenopus tropicalis, has been proposed as an alternative system; it shares all of the physical characteristics that make X. laevis a useful model but has the advantage of a diploid genome and short generation time. The rapid accumulation of genetic resources for this animal and the success of pilot mutagenesis screens have helped propel this model system forward. Transposable elements will provide invaluable tools for manipulating the frog genome. These integration systems are ideally suited to transgenesis and insertional mutagenesis strategies in the frog. The high fecundity of the frog combined with the ability to remobilize transposon transgenes integrated into frog genome will allow large-scale insertional mutagenesis screens to be performed in laboratories with modest husbandry capacities.     

SIP metagenomics identifies uncultivated Methylophilaceae as dimethylsulphide degrading bacteria in soil and lake sediment

Dimethylsulphide (DMS) has an important role in the global sulphur cycle and atmospheric chemistry. Microorganisms using DMS as sole carbon, sulphur or energy source, contribute to the cycling of DMS in a wide variety of ecosystems. The diversity of microbial populations degrading DMS in terrestrial environments is poorly understood. Based on cultivation studies, a wide range of bacteria isolated from terrestrial ecosystems were shown to be able to degrade DMS, yet it remains unknown whether any of these have important roles in situ. In this study, we identified bacteria using DMS as a carbon and energy source in terrestrial environments, an agricultural soil and a lake sediment, by DNA stable isotope probing (SIP). Microbial communities involved in DMS degradation were analysed by denaturing gradient gel electrophoresis, high-throughput sequencing of SIP gradient fractions and metagenomic sequencing of phi29-amplified community DNA. Labelling patterns of time course SIP experiments identified members of the Methylophilaceae family, not previously implicated in DMS degradation, as dominant DMS-degrading populations in soil and lake sediment. Thiobacillus spp. were also detected in ¹³C-DNA from SIP incubations. Metagenomic sequencing also suggested involvement of Methylophilaceae in DMS degradation and further indicated shifts in the functional profile of the DMS-assimilating communities in line with methylotrophy and oxidation of inorganic sulphur compounds. Overall, these data suggest that unlike in the marine environment where gammaproteobacterial populations were identified by SIP as DMS degraders, betaproteobacterial Methylophilaceae may have a key role in DMS cycling in terrestrial environments.     

Biometry and the IBS—Strength through Diversity

Summary .  The International Biometric Society (IBS) brings together members from a diversity of cultural backgrounds, organized into geographically based Regions and National Groups, and covering a diverse range of interests, in terms of both methodological topics and application areas. We briefly reflect on how the historical development of our science, society, and international conferences reflects this diversity, with a focus on the history of the British and Irish Region of the IBS. Then, by considering the cultural/geographical diversity of the society, and the scientific diversity of the society and biometricians, we identify both some strengths of the society (diverse topics for meetings arranged across the world, application of biometrical methods to diverse application areas, management of the society by members from a diversity of backgrounds) and also some current challenges (electronic delivery of journals and other information, the diversity of application areas addressed by members of the society, improving links with the scientific societies of those who motivate our research). Finally, we illustrate the diversity of scientific problems that each of us face in our roles as biometricians.