Zigzag Turning Preference of Freely Crawling Cells

The coordinated motion of a cell is fundamental to many important biological processes such as development, wound healing, and phagocytosis. For eukaryotic cells, such as amoebae or animal cells, the cell motility is based on crawling and involves a complex set of internal biochemical events. A recent study reported very interesting crawling behavior of single cell amoeba: in the absence of an external cue, free amoebae move randomly with a noisy, yet, discernible sequence of ‘run-and-turns’ analogous to the ‘run-and-tumbles’ of swimming bacteria. Interestingly, amoeboid trajectories favor zigzag turns. In other words, the cells bias their crawling by making a turn in the opposite direction to a previous turn. This property enhances the long range directional persistence of the moving trajectories. This study proposes that such a zigzag crawling behavior can be a general property of any crawling cells by demonstrating that 1) microglia, which are the immune cells of the brain, and 2) a simple rule-based model cell, which incorporates the actual biochemistry and mechanics behind cell crawling, both exhibit similar type of crawling behavior. Almost all legged animals walk by alternating their feet. Similarly, all crawling cells appear to move forward by alternating the direction of their movement, even though the regularity and degree of zigzag preference vary from one type to the other

The Quaternary Structure of the R-State of Escherichia coli Aspartate Transcarbamoylase in Solution Is Different from That in the Crystal and Is Modified by Mg 2+ ·ATP Binding

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Distinct T cell dynamics in lymph nodes during the induction of tolerance and immunity

Induction of immunity and peripheral tolerance requires contacts between antigen-bearing dendritic cells (DCs) and cognate T cells. Using real-time two-photon microscopy, we have analyzed the dynamics of CD8(+) T cells in lymph nodes during the induction of antigen-specific immunity or tolerance. At 15-20 h after the induction of immunity, T cells stopped moving and established prolonged interactions with DCs. In tolerogenic conditions, despite effective initial T cell activation and proliferation, naive T cells remained motile and established serial brief contacts with multiple DCs. Thus, stable DC-T cell interactions occur during the induction of priming, whereas brief contacts may contribute to the induction of T cell tolerance

Large differences are observed between the crystal and solution quaternary structures of allosteric aspartate transcarbamylase in the R state.

Solution scattering curves evaluated from the crystal structures of the T and R states of the allosteric enzyme aspartate transcarbamylase from Escherichia coli were compared with the experimental x-ray scattering patterns. Whereas the scattering from the crystal structure of the T state agrees with the experiment, large deviations reflecting a significant difference between the quaternary structures in the crystal and in solution are observed for the R state. The experimental curve of the R state was fitted by rigid body movements of the subunits in the crystal R structure which displace the latter further away from the T structure along the reaction coordinates of the T-->R transition observed in the crystals. Taking the crystal R structure as a-reference, it was found that in solution the distance between the catalytic trimers along the threefold axis is 0.34 nm larger and the trimers are rotated by 11 degrees in opposite directions around the same axis; each of the three regulatory dimers is rotated by 9 degrees around the corresponding twofold axis and displaced by 0.14 nm away from the molecular center along this axis

Direct observation in solution of a preexisting structural equilibrium for a mutant of the allosteric aspartate transcarbamoylase

Many signaling and metabolic pathways rely on the ability of some of the proteins involved to undergo a substrate-induced transition between at least two structural states. Among the various models put forward to account for binding and activity curves of those allosteric proteins, the Monod, Wyman, and Changeux model for allostery theory has certainly been the most influential, although a central postulate, the preexisting equilibrium between the low-activity, low-affinity quaternary structure and the high-activity, high-affinity quaternary structure states in the absence of substrates, has long awaited direct experimental substantiation. Upon substrate binding, allosteric Escherichia coli aspartate transcarbamoylase adopts alternate quaternary structures, stabilized by a set of interdomain and intersubunit interactions, which are readily differentiated by their solution x-ray scattering curves. Disruption of a salt link, which is observed only in the low-activity, low-affinity quaternary structure, between Lys-143 of the regulatory chain and Asp-236 of the catalytic chain yields a mutant enzyme that is in a reversible equilibrium between at least two states in the absence of ligand, a major tenet of the Monod, Wyman, and Changeux model. By using this mutant as a magnifying glass of the structural effect of ligand binding, a comparative analysis of the binding of carbamoyl phosphate (CP) and analogs points out the crucial role of the amine group of CP in facilitating the transition toward the high-activity, high-affinity quaternary state. Thus, the cooperative binding of aspartate in aspartate transcarbamoylase appears to result from the combination of the preexisting quaternary structure equilibrium with local changes induced by CP binding

A solution NMR study showing that active site ligands and nucleotides directly perturb the allosteric equilibrium in aspartate transcarbamoylase

The 306-kDa aspartate transcarbamoylase is a well studied regulatory enzyme, and it has emerged as a paradigm for understanding allostery and cooperative binding processes. Although there is a consensus that the cooperative binding of active site ligands follows the Monod–Wyman–Changeux (MWC) model of allostery, there is some debate about the binding of effectors such as ATP and CTP and how they influence the allosteric equilibrium between R and T states of the enzyme. In this article, the binding of substrates, substrate analogues, and nucleotides is studied, along with their effect on the R–T equilibrium by using highly deuterated, 1H,13C-methyl-labeled protein in concert with methyl-transverse relaxation optimized spectroscopy (TROSY) NMR. Although only the T state of the enzyme can be observed in spectra of wild-type unliganded aspartate transcarbamoylase, binding of active-site substrates shift the equilibrium so that correlations from the R state become visible, allowing the equilibrium constant (L′) between ligand-saturated R and T forms of the enzyme to be measured quantitatively. The equilibrium constant between unliganded R and T forms (L) also is obtained, despite the fact that the R state is “invisible” in spectra, by means of an indirect process that makes use of relations that emerge from the fact that ligand binding and the R–T equilibrium are linked. Titrations with MgATP unequivocally establish that its binding directly perturbs the R–T equilibrium, consistent with the Monod–Wyman–Changeux model. This study emphasizes the utility of modern solution NMR spectroscopy in understanding protein function, even for systems with aggregate molecular masses in the hundreds of kilodaltons