Development of a screening platform for directed evolution using the reef coral fluorescent protein ZsGreen as a solubility reporter.

Soluble proteins, with high expression levels, are preferred candidates for structural and functional studies. In cases of low expression, aggregation or inclusion body formation, time-consuming searches for optimal expression or refolding conditions are required. We have developed a high-throughput solubility engineering and screening platform for proteins that are expressed in an insoluble form in Escherichia coli with the aim of obtaining a broad spectrum of best hits with increased solubility in difficult to express target proteins. This process has been developed using error-prone PCR to introduce random base changes in genes of interest. Expression of mutated proteins in fusion with the reef coral fluorescent protein ZsGreen as a solubility marker has enabled the selection of more soluble variants. We have used a colony picker to achieve high-throughput selection of E.coli expressing more soluble target protein-ZsGreen fusions, with increased fluorescence. The whole process enables us to complete one round of mutation, screening and analysis of 20,000 potential soluble clones within approximately 8 weeks. We describe the development of the methods using different model proteins and show one example, the kinase domain from the human EphB2 receptor, as a successful application of the whole platform.

Regulation of notch endosomal sorting and signaling by Drosophila Nedd4 family proteins.

The Notch receptor mediates a short-range signal that regulates many cell fate decisions. The misregulation of Notch has been linked to cancer and to developmental disorders. Upon binding to its ligands, Delta (Dl) or Serrate (Ser), the Notch ectodomain is shed by the action of an ADAM protease. The Notch intracellular domain is subsequently released proteolytically from the membrane by Presenilin and translocates to the nucleus to activate the transcription factor, Suppressor of Hairless. We show in Drosophila that Notch signaling is limited by the activity of two Nedd4 family HECT domain proteins, Suppressor of deltex [Su(dx)] and DNedd4. We rule out models by which Su(dx) downregulates Notch through modulating Deltex or by limiting the adherens junction accumulation of Notch. Instead, we show that Su(dx) regulates the postendocytic sorting of Notch within the early endosome to an Hrs- and ubiquitin-enriched subdomain en route to the late endosome. We propose a model in which endocytic sorting of Notch mediates a decision between its activation and downregulation. Such intersections between trafficking routes may provide key points at which other signals can modulate Notch activity in both normal development and in the pathological misactivation of Notch.

Down-regulation of Notch target gene expression by Suppressor of deltex.

In Drosophila, Suppressor of deltex (Su(dx)) mutations display a wing vein gap phenotype resembling that of Notch gain of function alleles. The Su(dx) protein may therefore act as a negative regulator of Notch but its activity on actual Notch signalling levels has not been demonstrated. Here we show that Su(dx) does regulate the level of Notch signalling in vivo, upstream of Notch target genes and in different developmental contexts, including a previously unknown role in leg joint formation. Overexpression of Su(dx) was capable of blocking both the endogenous activity of Notch and the ectopic Notch signalling induced by the overexpression of Deltex, an intracellular Notch binding protein. In addition, using the conditional phenotype of the Su(dx)(sp) allele, we show that loss of Su(dx) activity is rapidly followed by an up-regulation of E(spl)mbeta expression, the immediate target of Notch signal activation during wing vein development. While Su(dx) adult wing vein phenotypes are quite mild, only affecting the distal tips of the veins, we show that the initial consequence of loss of Su(dx) activity is more severe than previously thought. Using a time-course experiment we show that the phenotype is buffered by feedback regulation illustrating how signalling networks can make development robust to perturbation.