Site-specific transgenesis in Xenopus.

Transgenesis is an essential, powerful tool for investigating gene function and the activities of enhancers, promoters, and transcription factors in the chromatin environment. In Xenopus, current methods generate germ-line transgenics by random insertion, often resulting in mosaicism, position-dependent variations in expression, and lab-to-lab differences in efficiency. We have developed and tested a Xenopus FLP-FRT recombinase-mediated transgenesis (X-FRMT) method. We demonstrate transgenesis of Xenopus laevis by FLP-catalyzed recombination of donor plasmid cassettes into F(1) tadpoles with host cassette transgenes. X-FRMT provides a new method for generating transgenic Xenopus. Once Xenopus lines harboring single host cassettes are generated, X-FRMT should allow for the targeting of transgenes to well-characterized integration site(s), requiring no more special reagents or training than that already common to most Xenopus labs.

Design of a filter train for precipitate removal in monoclonal antibody downstream processing.

Protein A chromatography has become widely established for the preparative purification of mAbs (monoclonal antibodies). Low pH elution from Protein A columns followed by neutralization can often lead to precipitation of impurities in the product stream, leading to a visually turbid solution. Pretreatment of the cell culture harvest stream with an increased surface area of the depth filter was found to reduce the magnitude of this problem through exploitation of the adsorptive properties of harvest depth filters. However, this was not a complete solution. Clarification of this turbid product stream prior to the polishing chromatographic steps in the downstream process posed significant filtration challenges. Development of a staged filtration process with the use of low plugging glass fibre depth filters as the first stage prior to membrane filtration through an absolute pore size membrane is described. Finally, a cost calculation is used to drive the selection of the final filter train for this application. The results presented here are expected to have wide applicability in mAb downstream processing as well as for other turbid solutions encountered in the downstream processing of other biomolecules.

Mouse cone arrestin gene characterization: promoter targets expression to cone photoreceptors.

Cone arrestin (CAR) is a novel member of the arrestin superfamily expressed in retinal cone photoreceptors and the pineal gland. To understand the regulatory mechanisms controlling its cone- and pineal-specific expression, and to facilitate further functional studies using gene knockout approaches, we characterized the genomic organization and the 5'-flanking region of the mouse CAR (mCAR) gene. The mCAR gene is comprised of 17 exons and 16 introns, encoding five alternatively spliced transcripts. A 215-bp proximal promoter fragment containing a TATA box, an Sp1 site and four cone-rod homeobox-binding sites is sufficient to direct expression in cultured retinoblastoma cells and in cone photoreceptors and the pineal gland in transgenic Xenopus laevis.