[
Cell,
2004]
In this issue of Cell, Inoue et al. (2004) reports that LIN-18, an atypical receptor tyrosine kinase related to mammalian Ryk and Drosophila Derailed, mediates Wnt signaling in parallel to LIN-17/Frizzled (Fz) during worm vulval development. LIN-18/Ryk and LIN-17/Fz appear to exhibit distinct Wnt specificity, and surprisingly, the LIN-18 intracellular domain may be dispensable.
[
Methods Cell Biol,
1995]
The ultimate goal of subcellular fractionation and biochemical purification is to better understand the relationships between structure and function of proteins and protein assemblies. Examples of such relationships with respect to specific gene products include the formation of stable complexes, elucidation of catalytic activities, and subcellular localization of the organellar and supramolecular levels. The detailed aspects of such relationships are not always readily predictable from genetic or molecular studies of the gene products or from their cellular localization by immunological methods. Subcellular fractionation and biochemical purification are generally prerequisites to experimental analysis of biochemical mechanisms underlying a biological phenomenon. These approaches can mutually enhance and interact with parallel cellular, genetic, and molecular analyses. To achieve such goals, methods for isolating proteins and protein assemblies must preserve both structural integrity and biological activity. Ideally, both objectives should be met; practically, it may be critical to know which of these conditions is true. In general, specific protocols must be designed for the optimal isolation, purification, and characterization of each specific protein of interest. Additionally, one wishes to achieve as high a yield as possible; however, each step in protein purification generally produces some reduction in yield...
[
Dev Biol,
2008]
One of the challenges to understanding nervous system development has been to establish how a fairly limited number of axon guidance cues can set up the patterning of very complex nervous systems. Studies on organisms with relatively simple nervous systems such as Drosophila melanogaster and C. elegans have provided many insights into axon guidance mechanisms. The axons of many neurons migrate along both the dorsal-ventral axis (DV) and the anterior-posterior (AP) at different phases of development, and in addition they may also cross the midline. Axon migration in the dorsal-ventral (DV) direction is mainly controlled by Netrins with their receptors; UNC-40/DCC and UNC-5, and the Slits with their receptors; Robo/SAX-3. Axon guidance in the anterior-posterior (AP) axis is mainly controlled by Wnts with their receptors; the Frizzleds/Fz. An individual axon may be subjected to opposing attractive and repulsive forces coming from opposite sides in the same axis but there may also be opposing cues in the other axis of migration. All the information from the cues has to be integrated within the growth cone at the leading edge of the migrating axon to elicit a response. Recent studies have provided insight into how this is achieved. Evidence suggests that the axis of axon migration is determined by the manner in which Netrin, Slit and Wnt receptors are polarized (localized) within the neuron prior to axon outgrowth. The same molecules are involved in both axon outgrowth and axon guidance, for at least some neurons in C. elegans, whether the cue is the attractive cue UNC-6/Netrin working though UNC-40/DCC or the repulsive cue SLT-1/Slit working though the receptor SAX-3/Robo (Adler et al., 2006, Chang et al., 2006, Quinn et al., 2006, 2008). The molecules involved in cell signaling in this case are polarized within the cell body of the neuron before process outgrowth and direct the axon outgrowth. Expression of the Netrin receptor UNC-40/DCC or the Slit receptor SAX-3/Robo in axons that normally migrate in the AP direction causes neuronal polarity reversal in a Netrin and Slit independent manner (Levy-Strumpf and Culotti 2007, Watari-Goshima et al., 2007). Localization of the receptors in this case is caused by the kinesin-related VAB-8L which appears to govern the site of axon outgrowth in these neurons by causing receptor localization. Therefore, asymmetric localization of axon guidance receptors is followed by axon outgrowth in vivo using the receptor''s normal cue, either attractive, repulsive or unknown cues.