Derek A. Applewhite

The spectraplakin Short stop is an actin-microtubule cross-linker that contributes to organization of the microtubule network.

The dynamics of actin and microtubules are coordinated in many cellular processes, but little is known about molecules mediating cross-talk. We describe intracellular dynamics of Shot in a structure-function analysis of its role as a cross-linker. Shot interacts with microtubules two ways through EB1 and along microtubule lattices by the GAS2 domain.

Responsive microtubule dynamics promote cell invasion by Trypanosoma cruzi

The American trypanosome, Trypanosoma cruzi, can invade non‐phagocytic cell types by a G‐protein‐mediated, calcium‐dependent mechanism, in which the cells natural puncture repair mechanism is usurped in order to recruit lysosomes to the parasite/host cell junction or ‘parasite synapse.’ The fusion of lysosomes necessary for construction of the nascent parasitophorous vacuole is achieved by directed trafficking along microtubules. We demonstrate altered host cell microtubule dynamics during the initial stages of the entry process involving de novo microtubule polymerization from the cytoplasmic face of the parasite synapse which appears to serve as a secondary microtubule organizing centre. The net result of these dynamic changes to the host cells microtubule cytoskeleton is the development of the necessary infrastructure for transport of lysosomes to the parasite synapse.

The actin-microtubule cross-linking activity of Drosophila Short stop is regulated by intramolecular inhibition

The authors investigated the regulation of the Drosophila actin-microtubule cross-linker Short stop (Shot) and found that Shot undergoes an intramolecular conformational change that regulates its cross-linking activity. This intramolecular interaction depends on Shots NH2-terminal actin-binding domain and EF-hand-GAS2 domain.

Imaging of the Cytoskeleton Using Live and Fixed Drosophila Tissue Culture Cells

In recent years, the convergence of multiple technologies and experimental approaches has led to the expanded use of cultured Drosophila cells as a model system. Their ease of culture and maintenance, susceptibility to RNA interference, and imaging characteristics have led to extensive use in both traditional experimental approaches as well as high-throughput RNAi screens. Here we describe Drosophila S2 cell culture and preparation for live-cell and fixed-cell fluorescence microscopy and scanning electron microscopy.

Ena/VASP processive elongation is modulated by avidity on actin filaments bundled by the filopodia crosslinker fascin

Ena/VASP are tetrameric assembly factors that bind F-actin barbed ends continuously while increasing their elongation rate within dynamic bundled networks such as filopodia. We used single-molecule TIRFM and developed a kinetic model to dissect Ena/VASP’s processive mechanism on bundled filaments. Notably, Ena/VASP’s processive run length increases with the number of both bundled filaments and Ena arms, revealing avidity facilitates enhanced processivity. Moreover, Ena tetramers form more filopodia than mutant dimer and trimers in Drosophila culture cells. Finally, enhanced processivity on trailing barbed ends of bundled filaments is an evolutionarily conserved property of Ena/VASP homologs and is specific to fascin-bundled filaments. These results demonstrate that Ena tetramers are tailored for enhanced processivity on fascin bundles and avidity of multiple arms associating with multiple filaments is critical for this process. Furthermore, we discovered a novel regulatory mechanism whereby bundle size and bundling protein specificity control activities of a processive assembly factor.

The Drosophila Cortactin Binding Protein 2 homolog, Nausicaa, regulates lamellipodial actin dynamics in a Cortactin-dependent manner.

Drosophila CG10915 is an uncharacterized protein coding gene with sequence similarity to human Cortactin Binding Protein 2 (CTTNBP2) and Cortactin Binding Protein 2 N-terminal like (CTTNBP2NL). We have named this gene Nausicaa (naus) and characterize it through a combination of quantitative live-cell total internal reflection fluorescence (TIRF) microscopy, electron microscopy, RNAi depletion, and genetics. We found that Naus co-localizes with F-actin and Cortactin in the lamellipodia of Drosophila S2R+ and D25c2 cells and this localization is lost following Cortactin or Arp2/3 depletion or by mutations that disrupt a conserved proline patch found in its mammalian homologs. Using Permeabilization Activated Reduction in Fluorescence (PARF) and Fluorescence Recovery after Photo-bleaching (FRAP), we find that depletion of Cortactin alters Naus dynamics leading to a decrease in its half-life. Furthermore, we discovered that Naus depletion in S2R+ cells led to a decrease in actin retrograde flow and a lamellipodia characterized by long, unbranched filaments. We demonstrate that these alterations to the dynamics and underlying actin architecture also affect D25c2 cell migration and decrease arborization in Drosophila neurons. We present the novel hypothesis that Naus functions to slow Cortactin’s disassociation from Arp2/3 nucleated branch junctions, thereby increasing both branch nucleation and junction stability.

A Cell-based Assay to Investigate Non-muscle Myosin II Contractility via the Folded-gastrulation Signaling Pathway in Drosophila S2R+ Cells

We have developed a cell-based assay using Drosophila cells that recapitulates apical constriction initiated by folded gastrulation (Fog), a secreted epithelial morphogen. In this assay, Fog is used as an agonist to activate Rho through a signaling cascade that includes a G-protein-coupled receptor (Mist), a Gα12/13 protein (Concertina/Cta), and a PDZ-domain-containing guanine nucleotide exchange factor (RhoGEF2). Fog signaling results in the rapid and dramatic reorganization of the actin cytoskeleton to form a contractile purse string. Soluble Fog is collected from a stable cell line and applied ectopically to S2R+ cells, leading to morphological changes like apical constriction, a process observed during developmental processes such as gastrulation. This assay is amenable to high-throughput screening and, using RNAi, can facilitate the identification of additional genes involved in this pathway.