Direct localization of monoclonal antibody-binding sites on Acanthamoeba myosin-II and inhibition of filament formation by antibodies that bind to specific sites on the myosin-II tail

Electron microscopy of myosin-II molecules and filaments reacted with monoclonal antibodies demonstrates directly where the antibodies bind and shows that certain antibodies can inhibit the polymerization of myosin-II into filaments. The binding sites of seven of 23 different monoclonal antibodies were localized by platinum shadowing of myosin monomer-antibody complexes. The antibodies bind to a variety of sites on the myosin-II molecule, including the heads, the proximal end of the tail near the junction of the heads and tail, and the tip of the tail. The binding sites of eight of the 23 antibodies were also localized on myosin filaments by negative staining. Antibodies that bind to either the myosin heads or to the proximal end of the tail decorate the ends of the bipolar filaments. Some of the antibodies that bind to the tip of the myosin-II tail decorate the bare zone of the myosin-II thin filament with 14-nm periodicity. By combining the data from these electron microscope studies and the peptide mapping and competitive binding studies we have established the binding sites of 16 of 23 monoclonal antibodies. Two of the 23 antibodies block the formation of myosin-II filaments and given sufficient time, disassemble preformed myosin-II filaments. Both antibodies bind near one another at the tip of the myosin-II tail and are those that decorate the bare zone of preformed bipolar filaments with 14-nm periodicity. None of the other antibodies affect myosin filament formation, including one that binds to another site near the tip of the myosin-II tail. This demonstrates that antibodies can inhibit polymerization of myosin-II, but only when they bind to key sites on the tail of the molecule.     

Intrinsic Protein Fluorescence Interferes with Detection of Tear Glycoproteins in SDS-Polyacrylamide Gels Using Extrinsic Fluorescent Dyes

Intrinsic protein fluorescence may interfere with the visualization of proteins after SDS-polyacrylamide electrophoresis. In an attempt to analyze tear glycoproteins in gels, we ran tear samples and stained the proteins with a glycoprotein-specific fluorescent dye. The fluorescence detected was not limited to glycoproteins. There was strong intrinsic fluorescence of proteins normally found in tears after soaking the gels in 40% methanol plus 1-10% acetic acid and, to a lesser extent, in methanol or acetic acid alone. Nanograms of proteins gave visible native fluorescence and interfere with extrinsic fluorescent dye detection. Poly-L-lysine, which does not contain intrinsically fluorescent amino acids, did not fluoresce.     

bullwinkle is required for epithelial morphogenesis during Drosophila oogenesis

Many organs, such as the liver, neural tube, and lung, form by the precise remodeling of flat epithelial sheets into tubes. Here we investigate epithelial tubulogenesis in Drosophila melanogaster by examining the development of the dorsal respiratory appendages of the eggshell. We employ a culture system that permits confocal analysis of stage 10-14 egg chambers. Time-lapse imaging of GFP-Moesin-expressing egg chambers reveals three phases of morphogenesis: tube formation, anterior extension, and paddle maturation. The dorsal-appendage-forming cells, previously thought to represent a single cell fate, consist of two subpopulations, those forming the tube roof and those forming the tube floor. These two cell types exhibit distinct morphological and molecular features. Roof-forming cells constrict apically and express high levels of Broad protein. Floor cells lack Broad, express the rhomboid-lacZ marker, and form the floor by directed cell elongation. We examine the morphogenetic phenotype of the bullwinkle (bwk) mutant and identify defects in both roof and floor formation. Dorsal appendage formation is an excellent system in which cell biological, molecular, and genetic tools facilitate the study of epithelial morphogenesis.     

Division of labor: Subsets of dorsal-appendage-forming cells control the shape of the entire tube

The function of an organ relies on its form, which in turn depends on the individual shapes of the cells that create it and the interactions between them. Despite remarkable progress in the field of developmental biology, how cells collaborate to make a tissue remains an unsolved mystery. To investigate the mechanisms that determine organ structure, we are studying the cells that form the dorsal appendages (DAs) of the Drosophila melanogaster eggshell. These cells consist of two differentially patterned subtypes: roof cells, which form the outward-facing roof of the lumen, and floor cells, which dive underneath the roof cells to seal off the floor of the tube. In this paper, we present three lines of evidence that reveal a further stratification of the DA-forming epithelium. Laser ablation of only a few cells in the anterior of the region causes a disproportionately severe shortening of the appendage. Genetic alteration through the twin peaks allele of tramtrack69 (ttk^twk), a female-sterile mutation that leads to severely shortened DAs, causes no such shortening when removed from a majority of the DA-forming cells, but rather, produces short appendages only when removed from cells in the very anterior of the tube-forming tissue. Additionally we show that heterotrimeric G-protein function is required for DA morphogenesis. Like TTK69, Gβ13F is not required in all DA-forming follicle cells but only in the floor and leading roof cells. The different phenotypes that result from removal of Gβ13F from each region demonstrate a striking division of function between different DA-forming cells. Gβ mutant floor cells are unable to control the width of the appendage while Gβ mutant leading roof cells fail to direct the elongation of the appendage and the convergent-extension of the roof-cell population.     

Native nonmuscle myosin II stability and light chain binding in Drosophila melanogaster

Native nonmuscle myosin IIs play essential roles in cellular and developmental processes throughout phylogeny. Individual motor molecules consist of a heterohexameric complex of three polypeptides which, when properly assembled, are capable of force generation. Here, we more completely characterize the properties, relationships and associations that each subunit has with one another in Drosophila melanogaster. All three native nonmuscle myosin II polypeptide subunits are expressed in close to constant stoichiometry to each other throughout development. We find that the stability of two subunits, the heavy chain and the regulatory light chain, depend on one another whereas the stability of the third subunit, the essential light chain, does not depend on either the heavy chain or regulatory light chain. We demonstrate that heavy chain aggregates, which form when regulatory light chain is lacking, associate with the essential light chain in vivo-thus showing that regulatory light chain association is required for heavy chain solubility. By immunodepletion we find that the majority of both light chains are associated with the nonmuscle myosin II heavy chain but pools of free light chain and/or light chain bound to other proteins are present. We identify four myosins (myosin II, myosin V, myosin VI and myosin VIIA) and a microtubule-associated protein (asp/Abnormal spindle) as binding partners for the essential light chain (but not the regulatory light chain) through mass spectrometry and co-precipitation. Using an in silico approach we identify six previously uncharacterized genes that contain IQ-motifs and may be essential light chain binding partners.     

Contractile protein biochemistry in the Pollard Lab in Baltimore

We describe our search for the molecular mechanisms of cell motility with personal recollections of bucket biochemistry in Tom Pollards Lab at the Johns Hopkins, circa 1980.     

GROWTH AND LABILITY OF CHAETOPTERUS OOCYTE MITOTIC SPINDLES ISOLATED IN THE PRESENCE OF PORCINE BRAIN TUBULIN

Purified tubulin solutions stabilized and augmented the birefringence (BR) of isolated Chaetopterus spindles. Tubulin was extracted from pig brain tissue in cold PEG buffer (0.1 M piperazine-N-N'-bis[2-ethane sulfonic acid], 1 mM ethylene bis-[oxyethylenenitrilo]tetraacetate, [EGTA], 2.5 mM guanosine triphosphate, [GTP], pH 6.94, at 25°C), and purified by two cycles of a reversible, temperature-dependent assembly-disassembly procedure. The spindle BR of the meiotic metaphase-arrested oocytes of Chaetopterus decreased linearly at a rate of 1.5 nm/min when perfused with PEG buffer without tubulin. In this hypotonic, calcium-chelating solution, the cell lysed within 1.5 min, and after a brief, transient rise, the BR disappeared in ca. 4 min from the time of buffer application. Cells perfused with tubulin in PEG buffer also showed BR decay at the same rate until cell lysis. Immediately upon cell lysis the spindle BR increased, initially at ca. 2.3 nm/min and then more slowly until the BR attained or exceeded intact cell values. Spindle and asters grew considerably larger than those in intact cells. From the kinetics of the transient BR increase after lysis, we infer that, initially, Chaetopterus cytoplasmic tubulin contributes to increased BR; further augmentation required added pig brain tubulin and most probably reflects the addition and incorporation of heterologous porcine tubulin into the spindle and asters. Isolated, augmented spindles depolymerized rapidly at 6°C. Upon return to 23°C, spindle BR returned slowly in tubulin-PEG. The BR of the isolates also decayed in solutions containing calcium ions 2.5 mM in excess of the EGTA. However, the isolates did not respond, or responded very slowly, to 1 mM colchicine or Colcemid and to dilution of tubulin with PEG solution. Microinjection into Chaetopterus oocytes of tubulin-PEG, but not PEG alone, enhanced spindle and aster BR which reversibly disappeared upon chilling the cell.