Thymosin-beta(4) changes the conformation and dynamics of actin monomers.

Thymosin-beta(4) (Tbeta(4)) binds actin monomers stoichiometrically and maintains the bulk of the actin monomer pool in metazoan cells. Tbeta(4) binding quenches the fluorescence of N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (AEDANS) conjugated to Cys(374) of actin monomers. The K(d) of the actin-Tbeta(4) complex depends on the cation and nucleotide bound to actin but is not affected by the AEDANS probe. The different stabilities are determined primarily by the rates of dissociation. At 25 degrees C, the free energy of Tbeta(4) binding MgATP-actin is primarily enthalpic in origin but entropic for CaATP-actin. Binding is coupled to the dissociation of bound water molecules, which is greater for CaATP-actin than MgATP-actin monomers. Proteolysis of MgATP-actin, but not CaATP-actin, at Gly(46) on subdomain 2 is >12 times faster when Tbeta(4) is bound. The C terminus of Tbeta(4) contacts actin near this cleavage site, at His(40). By tritium exchange, Tbeta(4) slows the exchange rate of approximately eight rapidly exchanging amide protons on actin. We conclude that Tbeta(4) changes the conformation and structural dynamics ("breathing") of actin monomers. The conformational change may reflect the unique ability of Tbeta(4) to sequester actin monomers and inhibit nucleotide exchange.

Calcium signalling during chemotaxis.

The role of Ca2+ in chemotaxis of eosinophils from the newt Taricha granulosa was investigated using fluorescent indicators and digital imaging microscopy. In response to serum chemoattractant, cytoplasmic Ca2+ concentration ([Ca2+]i) rises prior to polarization. In polarized locomoting cells [Ca2+]i gradients (tail-high-front-low) are always seen, and when cells turn [Ca2+]i rises transiently and falls fastest and furthest in the new direction of cell motion. These Ca2+ signals, which are required for polarization and locomotion, arise from Ca2+ derived from internal stores released in response to inositol 1,4,5-trisphosphate (InsP3) (because microinjected heparin fully blocks them). 1,2-Diacyl-sn-glycerol (DAG), which is co-produced with InsP3, has an inhibitory effect on Ca2+ signals, an effect apparently mediated by protein kinase C. Studies with caged InsP3 reveal that InsP3-responsive stores appear to be concentrated in the nuclear and microtubule-organizing centre regions and that InsP3 moves so rapidly within the cell that it is effectively a global secondary messenger. Thus, stable [Ca2+] gradients observed during unidirectional migration appear to result from the concentration of InsP3-responsive Ca2+ stores in the rear of the cell. By contrast, we propose that reorientation of the [Ca2+] gradient prior to a change in direction of motion results from the joint actions of InsP3 and DAG, with InsP3 acting as a global secondary messenger stimulating Ca2+ release and DAG, through protein kinase C, acting as a spatially restricted secondary messenger inhibiting [Ca2+] increases locally near the site of chemotactic stimulation.

Expression and phosphorylation of the Listeria monocytogenes ActA protein in mammalian cells.

Movement of Listeria monocytogenes within infected eukaryotic cells provides a simple model system to study the mechanism of actin-based motility in nonmuscle cells. The actA gene of L. monocytogenes is required to induce the polymerization of host actin filaments [Kocks, C., Gouin, E., Tabouret, M., Berche, P., Ohayon, H. & Cossart, P. (1990) Cell 68, 521-531; Domann, E., Wehland, J., Rohde, M., Pistor, S., Hartl, M., Goebel, W., Leimeister-Wachter, M., Wuenscher, M. & Chakraborty, T. (1992) EMBO J. 11, 1981-1990]. In this study, an in-frame deletion mutation within the actA gene was constructed and introduced into the L. monocytogenes chromosome by allelic exchange. This mutation resulted in a decrease (3 orders of magnitude) in virulence for mice. In tissue culture cells, the actA mutant was absolutely defective for the nucleation of actin filaments and consequently was impaired in cell-to-cell spread. Antiserum raised to a synthetic peptide encompassing the proline-rich repeat (DFPPPPTDEEL) of ActA was used to characterize the expression of the ActA protein. The ActA protein derived from extracellular bacteria migrated as a 97-kDa polypeptide upon SDS/PAGE, whereas the protein from infected cells migrated as three distinct polypeptides, one that comigrated with the 97-kDa extracellular form and two slightly larger species. Treatment of infected cells with okadaic acid resulted in decreased amounts of all forms of ActA and the appearance of a larger species of ActA. Phosphatase treatment of ActA immunoprecipitated from intracellular bacteria resulted in conversion of the larger two species to the 97-kDa form. Labeling of infected cells with 32Pi followed by immunoprecipitation showed that the largest molecular form of ActA was phosphorylated. Taken together, these data indicate that ActA is phosphorylated during intracellular growth. The significance of the intracellular modification of ActA is not known, but we speculate that it may modulate the intracellular activity of ActA.

Chemotaxis of newt eosinophils: calcium regulation of chemotactic response.

Local chemical events underlying chemotaxis were characterized in a new model cell, the newt eosinophil. These cells exhibit a chemotactic response to a trypsin-sensitive component of newt serum. Ca2+ plays a role in this process, since treatments expected to diminish Ca2+ availability from the medium [ethylene glycol-bis (beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid, Co2+, and verapamil], to break down transmembrane Ca2+ gradients (ionomycin), or to interfere with the function of intracellular Ca2+ stores (caffeine and neomycin) inhibited cell polarization and movement. Using imaging techniques we found that cytosolic Ca2+ concentration ([Ca2+]i) increased in response to newt serum. Migrating newt eosinophils exhibited a dynamic heterogeneous distribution of [Ca2+]i. [Ca2+]i was elevated in cells undergoing a change of direction relative to cells migrating persistently in one direction. Migrating cells contained gradients of [Ca2+]i along their long axis, with the front of the cell having consistently lower [Ca2+]i than the rear. When cells were loaded with the cell-permeant form of fura 2, fura 2 acetoxymethyl ester, a caffeine-sensitive membrane-delimited region of elevated [Ca2+]i was seen associated with the microtubule organizing center. A model is proposed relating the distribution of [Ca2+]i and the location of the external stimulus to the generation and interaction of substances within the cell that both simulate and inhibit increases in [Ca2+]i.

Calcium gradients underlying polarization and chemotaxis of eosinophils.

The concentration of intracellular free calcium ([Ca2+]i) in polarized eosinophils was imaged during chemotaxis by monitoring fluorescence of the calcium-sensitive dye Fura-2 with a modified digital imaging microscope. Chemotactic stimuli caused [Ca2+]i to increase in a nonuniform manner that was related to cell activity. In cells moving persistently in one direction, [Ca2+]i was highest at the rear and lowest at the front of the cell. Before cells turned, [Ca2+]i transiently increased. The region of the cell that became the new leading edge had the lowest [Ca2+]i. These changes in [Ca2+]i provide a basis for understanding the organization and local activity of cytoskeletal proteins thought to underlie the directed migration of many cells.