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4 results

  • 15 - Smooth Muscle

  • Christopher L.-H. Huang, University of Cambridge
  • Book:
    Keynes & Aidley's Nerve and Muscle
    Published online:
    07 November 2020
    Print publication:
    19 November 2020, pp 252-270

  • Summary

    Smooth muscle cells are adapted for slow, sustained contractions reducing the lumina of the tubular structures in which they occur. These are often paced by networks of interstitial cells of Cajal. The latter are recurrently depolarised by Ano1-Cl- channel opening, triggered by inositol trisphosphate induced store Ca2+ release. This triggers T-type Ca2+ current causing propagating slow waves then transmitted, via gap junctions, to smooth muscle cells. The resulting smooth muscle cell activation by L-type Ca2+ channels elicits Ca2+-induced sarcoplasmic reticular Ca2+ release. Additional autonomic and local transmitter driven pharmacomechanical coupling mechanisms mediated by a range of G-proteins also promote second-messenger-mediated muscle contraction or relaxation. Cross-bridge activity is activated by a combined Ca2+-calmodulin-mediated caldesmon dissociation from thin filament actin and myosin light chain kinase activation. Termination of cross bridge cycling leads to either muscle relaxation or latch-bridge formation, permitting sustained shortening in an absence of ATP-dependent energy expenditure.

  • 8 - Synaptic Transmission in the Nervous System

  • Christopher L.-H. Huang, University of Cambridge
  • Book:
    Keynes & Aidley's Nerve and Muscle
    Published online:
    07 November 2020
    Print publication:
    19 November 2020, pp 106-120

  • Summary

    Central nervous system function depends on synaptic transmission involving either chemical-transmitter-mediated or direct electrical coupling between neurones. Transmitter activation of excitatory and inhibitory synapses respectively produce postsynaptic membrane depolarisation and hyperpolarisation in turn increasing or decreasing likelihoods of action potential firing by the targetted neuron. Further variants of neuron-neuron interactions include inhibition at the level of presynaptic terminals and G-protein dependent slow synaptic potentials. Some central nervous system synapses additionally show longer-term potentiation or depression phenomena with repeated activity produced by intracellular signaling mechanisms; these may underly memory. Finally, direct electrical synaptic connections between cells can synchronise firing between neurones. Release of K+ and transmitter glutamate by central neurones during intense electrical activity potentially perturbs their extracellular environment. This is normally corrected by transport activity in their closely related glial cells. Malfunctions in this buffering function predisposes to cortical spreading depression phenomena clinically associated with migraine aura.

  • Role of the switch II region in the conformational transition of activation of Ha-ras-p21

  • JOSÉ FERNANDO DÍAZ, MARÍA MILAGROSA ESCALONA, STEVEN KUPPENS, YVES ENGELBORGHS
  • Journal:
    Protein Science / Volume 9 / Issue 2 / February 2000
    Published online by Cambridge University Press:
    01 February 2000, pp. 361-368
    Print publication:
    February 2000

  • The role of the switch II region in the conformational transition of activation of Ha-ras-p21 has been investigated by mutating residues predicted to act as hinges for the conformational transition of this loop (Ala59, Gly60, and Gly75) (Diaz JF, Wroblowski B, Schlitter J, Engelborghs Y, 1997, Proteins 28:434–451), as well as mutating the catalytic residue Gln61. The proposed mutations of the hinge residues decrease the rate of the conformational transition of activation as measured by the binding of BeF3 to the GDP-p21 complex. Also, the thermodynamic parameters of the binding reaction are altered by a factor between three and five, depending on the temperature. (Due to changes in activation and reaction enthalpies, partially compensated by entropy changes.) The control mutation Q61H in which only the catalytic residue is changed has only a limited effect on the kinetic rate constants of the conformational transition and on the thermodynamic parameters of the reaction.

    The fact that mutations of the hinge residues of the switch II region affect both the binding of the phosphate analog and the conformational transition of activation indicates that the switch II is implicated both in the early and the late states of the transition.

  • Characterization of the hinges of the effector loop in the reaction pathway of the activation of ras-proteins. Kinetics of binding of beryllium trifluoride to V29G and I36G mutants of Ha-ras-p21

  • STEVEN KUPPENS, JOSÉ FERNANDO DÍAZ, YVES ENGELBORGHS
  • Journal:
    Protein Science / Volume 8 / Issue 9 / September 1999
    Published online by Cambridge University Press:
    01 September 1999, pp. 1860-1866
    Print publication:
    September 1999

  • This work experimentally confirms the pathway of activation of Ha-ras-p21, which was calculated by the method of Targeted Molecular Dynamics (TMD) (Díaz JF, Wroblowski B, Schlitter J, Engelborghs Y, 1997a, Proteins Struct Funct Genet 28:434–451). The process can be studied experimentally by analyzing the binding of BeF3 to the GDP complex of the active fluorescent mutant Y32W (Díaz JF, Sillen A, Engelborghs Y, 1997b, J Biol Chem 227:23138–23143). Two mutants, V29G and I36G, have been constructed at both sides of the effector loop of the active fluorescent mutant. This was done to check the proposed reaction pathway and to provide further insight into the mechanism of the activation of ras proteins. Both mutations accelerate the conformational isomerization with two orders of magnitude, demonstrating convincingly the role of these residues as hinges of the effector loop in one or more of the transitions of the conformational change. These results provide experimental support to the pathway calculated by TMD analysis.