Pol II caught speeding by single gene imaging.

and anterograde transport between the ER and Golgi (Strating & Martens, 2009), are required for Wg secretion by S2 cells. Similarly, knockdown by transgenic RNAi shows that p24 proteins are required for normal levels of Wg secretion in Drosophila wing imaginal discs (Buechling et al, 2011; Port et al, 2011). As with Evi, this requirement seems to be relatively specific, since general secretion and the secretion of other signalling proteins, including the lipid-modified morphogen Hedgehog, are unaffected by p24 knockdown. Buechling et al also assessed the role of p24 proteins in WntD secretion. They found that RNAi against opossum (opm), one of the p24 members, prevents WntD secretion in cultured cells. They also show that the phenotypes of opm mutants and WntD mutant embryos resemble each other (Buechling et al, 2011). Therefore, while Evi is specifically required for the secretion of acylated Wnts, p24 proteins could contribute to the secretion of all Wnts. This function is likely to be conserved since the mammalian homologue of Opm, TMED5, is required for Wnt1 signalling, at least in a mammalian cell culture assay (Buechling et al, 2011). To gain understanding of the role of p24 proteins in Wnt secretion, both groups analysed the subcellular localization of Wg following p24 knockdown. They found accumulation in the ER and concomitant depletion in the Golgi, as indicated by reduced co-localization with Golgi markers (Fig 1Bi). They also found that p24 knockdown prevents Wg from stabilizing Evi in producing cells, suggesting that the stabilizing influence of Wg requires its exit from the ER (Buechling et al, 2011; Port et al, 2011). These results lead the authors to propose that the loss of p24 prevents the transport of Wg from the ER to the Golgi. Importantly, immunoprecipitation experiments suggest that Wg might interact physically with Opm and Emp24 (also known as CHOp24). This led both sets of authors to postulate a model whereby p24 proteins act as cargo receptors to escort Wnt proteins from the ER to the Golgi, whereupon they can bind to Evi, which will escort them to the plasma membrane. Thus, in this context, p24 proteins seem to have an anterograde function. Although both studies highlight the role of p24 proteins in Wnt secretion, they disagree on the relative importance of the various family members. Among the nine predicted p24 proteins encoded by the Drosophila genome, only Éclair and Emp24/CHOp24 were found to be required for Wg secretion by Port et al (2011; Fig 1Bii). By contrast, Buechling et al found that Opm, Emp24/CHOp24 and p24-1 all play a role in Wg secretion (fig 1Biii). Thus, only Emp24/CHOp24 is found by both groups to be essential for Wg secretion. Although functional redundancy among p24 proteins could explain why the removal of a single p24 protein has a relatively weak phenotype, there is no simple explanation as to why the very similar assays used by the two groups do not lead to identical conclusions. These differences could be worked out by the exchange of reagents and protocols. Regardless of the discrepancies, the two studies provide an important step in our understanding of Wnt secretion by demonstrating that Wnts engage with specialized components of the secretory machinery as early as in the ER. It might be relevant that the anterograde function of p24 proteins is directed at glycophosphatidylinositol (GPI)-anchored proteins, which have been shown to partition in raft-like microdomains (Strating & Martens, 2009). It is conceivable that GPI-anchored proteins, as well as Wnts, gather in a subdomain of the ER where they could both interact with p24 proteins and set off along their specialized secretory pathways. Wnt targeting to specialized membrane domains could in principle be mediated by their lipid moieties (Bartscherer & Boutros, 2008; Port & Basler, 2010). However, the process might turn out to be more complex if it is confirmed that p24 proteins are also required for the secretion of non-acylated Wnts (for example, WntD), as suggested by Buechling et al. In any case, it will be interesting to determine the precise molecular mechanism underlying the functional interaction between Wnts and p24 proteins as it is likely to explain how Wnts are allowed to exit the ER and start their journey out of the cell.