pTransgenesis: a cross-species, modular transgenesis resource.

As studies aim increasingly to understand key, evolutionarily conserved properties of biological systems, the ability to move transgenesis experiments efficiently between organisms becomes essential. DNA constructions used in transgenesis usually contain four elements, including sequences that facilitate transgene genome integration, a selectable marker and promoter elements driving a coding gene. Linking these four elements in a DNA construction, however, can be a rate-limiting step in the design and creation of transgenic organisms. In order to expedite the construction process and to facilitate cross-species collaborations, we have incorporated the four common elements of transgenesis into a modular, recombination-based cloning system called pTransgenesis. Within this framework, we created a library of useful coding sequences, such as various fluorescent protein, Gal4, Cre-recombinase and dominant-negative receptor constructs, which are designed to be coupled to modular, species-compatible selectable markers, promoters and transgenesis facilitation sequences. Using pTransgenesis in Xenopus, we demonstrate Gal4-UAS binary expression, Cre-loxP-mediated fate-mapping and the establishment of novel, tissue-specific transgenic lines. Importantly, we show that the pTransgenesis resource is also compatible with transgenesis in Drosophila, zebrafish and mammalian cell models. Thus, the pTransgenesis resource fosters a cross-model standardization of commonly used transgenesis elements, streamlines DNA construct creation and facilitates collaboration between researchers working on different model organisms.

Intact RNA-binding domains are necessary for structure-specific DNA binding and transcription control by CBTF122 during Xenopus development.

CBTF122 is a subunit of the Xenopus CCAAT box transcription factor complex and a member of a family of double-stranded RNA-binding proteins that function in both transcriptional and post-transcriptional control. Here we identify a region of CBTF122 containing the double-stranded RNA-binding domains that is capable of binding either RNA or DNA. We show that these domains bind A-form DNA in preference to B-form DNA and that the -59 to -31 region of the GATA-2 promoter (an in vivo target of CCAAT box transcription factor) adopts a partial A-form structure. Mutations in the RNA-binding domains that inhibit RNA binding also affect DNA binding in vitro. In addition, these mutations alter the ability of CBTF122 fusions with engrailed transcription repressor and VP16 transcription activator domains to regulate transcription of the GATA-2 gene in vivo. These data support the hypothesis that the double-stranded RNA-binding domains of this family of proteins are important for their DNA binding both in vitro and in vivo.