Presynaptic CK2 promotes synapse organization and stability by targeting Ankyrin2

The precise regulation of synapse maintenance is critical to the development and function of neuronal circuits. Using an in vivo RNAi screen targeting the Drosophila kinome and phosphatome, we identify 11 kinases and phosphatases controlling synapse stability by regulating cytoskeletal, phospholipid, or metabolic signaling. We focus on casein kinase 2 (CK2) and demonstrate that the regulatory (β) and catalytic (α) subunits of CK2 are essential for synapse maintenance. CK2α kinase activity is required in the presynaptic motoneuron, and its interaction with CK2β, mediated cooperatively by two N-terminal residues of CK2α, is essential for CK2 holoenzyme complex stability and function in vivo. Using genetic and biochemical approaches we identify Ankyrin2 as a key presynaptic target of CK2 to maintain synapse stability. In addition, CK2 activity controls the subcellular organization of individual synaptic release sites within the presynaptic nerve terminal. Our study identifies phosphorylation of structural synaptic components as a compelling mechanism to actively control the development and longevity of synaptic connections.     

Preadapted for invasiveness: do species traits or their plastic response to shading differ between invasive and non‐invasive plant species in their native range?

Aim Species capable of vigorous growth under a wide range of environmental conditions should have a higher chance of becoming invasive after introduction into new regions. High performance across environments can be achieved either by constitutively expressed traits that allow for high resource uptake under different environmental conditions or by adaptive plasticity of traits. Here we test whether invasive and non‐invasive species differ in presumably adaptive plasticity. Location Europe (for native species); the rest of the world and North America in particular (for alien species). Methods We selected 14 congeneric pairs of European herbaceous species that have all been introduced elsewhere. One species of each pair is highly invasive elsewhere in the world, particularly so in North America, whereas the other species has not become invasive or has spread only to a limited degree. We grew native plant material of the 28 species under shaded and non‐shaded conditions in a common garden experiment, and measured biomass production and morphological traits that are frequently related to shade tolerance and avoidance. Results Invasive species had higher shoot–root ratios, tended to have longer leaf‐blades, and produced more biomass than congeneric non‐invasive species both under shaded and non‐shaded conditions. Plants responded to shading by increasing shoot–root ratios and specific leaf area. Surprisingly, these shade‐induced responses, which are widely considered to be adaptive, did not differ between invasive and non‐invasive species. Main conclusions We conclude that high biomass production across different light environments pre‐adapts species to become invasive, and that this is not mediated by plasticities of the morphological traits that we measured.     

Uptake of fluorescent fatty acids by erythroleukemia cells. Effect of differentiation

The uptake of a fluorescent derivative of a fatty acid (FDFA), 12-(1-pyrene) dodecanoic acid (P12) by murine erythroleukemia (MEL) cells was studied. Because of the intense fluorescence of the pyrene ring, the association of P12 with intact cells could be analysed using a fluorescence microscope or a fluorescence-activated cell sorter (FACS), and the incorporation of P12 into cellular lipids could be quantified, following their extraction in a spectrofluorimeter. These procedures indicated that P12 uptake and intracellular utilization are reduced, following induction of erythrodifferentiation by dimethylsulfoxide (DMSO) or hexamethylene-bis-acetamide (HMBA). The differences in the fluorescence observed following exposure to P12 permitted us to separate a mixture of differentiated and undifferentiated cells into two distinct cell subpopulations; the high fluorescence population consisted mainly of undifferentiated cells, and the low one of differentiated cells. The results of this study suggest that fluorescent fatty acids are useful for distinguishing between and sorting cells at different stages of differentiation.     

Continuous spectrofluorometric measurements of uptake by cultured cells of 12-(1-pyrene)-dodecanoic acid from its complex with albumin.

Aqueous dispersions of 12-(1-pyrene)-dodecanoic acid (P12), a medium-chain fatty acid to which the fluorescent probe pyrene has been covalently linked, shows a considerable increase in fluorescence when the probe is introduced into a hydrophobic environment. This enables the uptake of P12 by liposomes and cells to be followed directly in a spectrofluorometer, without separating the cells from the P12-containing medium. In the present study, we show that complexing P12 to albumin produced a very high fluorescence emission intensity. This made direct measurements of the uptake by cells of albumin-bound P12 impossible. Such direct measurements could, however, be made using albumin which had been interacted with trinitrobenzenesulphonic acid (TNBS). The yellow trinitrophenyl (TNP) residues, which were thereby covalently linked to the albumin, quenched the fluorescence of pyrene in the TNP-albumin/P12 complex. Upon release of the P12 molecules from this complex and their subsequent uptake by cells, fluorescence increased. This technique was utilized for the continuous monitoring of the uptake of P12 by different cell types and cells at various stages of maturation.     

Evolutionary conservation of the human homologue of the yeast cell cycle control gene cdc2 and assignment of Cd2 to chromosome 10

Summary The human homologue of the fission yeast Schizosaccharomyces pombe cell cycle control gene cdc2 has been assigned to chromosome 10. DNA hybridization reveals that this gene is highly conserved in vertebrates. The human CDC2 gene probe detects a simple two-allele polymorphism in Taq1-digested DNA.