Ca2+ Activation of the cPLA2 C2 Domain:  Ordered Binding of Two Ca2+ Ions with Positive Cooperativity

Malmberg, Nathan J.; Varma, Sameer; Jakobsson, Eric; Falke, Joseph J.

doi:10.1021/bi0482405

Cited by 19 publications

(16 citation statements)

References 49 publications

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“…The need for high local densities to stabilize ion binding can therefore, at times, result in close similarities between the ion-complexed and apo-state structures of ion binding sites. This aspect of ion binding has been observed for numerous proteins, with more recent examples coming from K-channels,69 thrombins70 and cytosolic phospholipases,71, 72 where the structures of the apo and ion-complexed states are similar in the sense that they do not have different orders of ligand densities in their binding sites. Note also that the dependence of free energies on ligand concentrations is logarithmic, which allows binding sites the freedom to explore configurational space before changes in ligand densities begin to alter the energetics of ion binding appreciably.…”

Section: Resultsmentioning

confidence: 87%

Structural Transitions in Ion Coordination Driven by Changes in Competition for Ligand Binding

2008

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Transferring Na + and K + ions from their preferred coordination states in water to states having different coordination numbers incurs a free energy cost. In several examples in nature, however, these ions readily partition from aqueous-phase coordination states into spatial regions having much higher coordination numbers. Here we utilize statistical theory of solutions, quantum chemical simulations, classical mechanics simulations and structural informatics to understand this aspect of ion partitioning. Our studies lead to the identification of a specific role of the solvation environment in driving transitions in ion coordination structures. Although ion solvation in liquid media is an exergonic reaction overall, we find it is also associated with considerable free energy penalties for extracting ligands from their solvation environments to form coordinated ion complexes. Reducing these penalties increases the stabilities of higher-order coordinations and brings down the energetic cost to partition ions from water into over-coordinated binding sites in biomolecules. These penalties can be lowered via a reduction in direct favorable interactions of the coordinating ligands with all atoms other than the ions themselves. A significant reduction in these penalties can, in fact, also drive up ion coordination preferences. Similarly, an increase in these penalties can lower ion coordination preferences, akin to a Hofmeister effect. Since such structural transitions are effected by the properties of the solvation phase, we anticipate that they will also occur for other ions. The influence of other factors, including ligand density, ligand chemistry and temperature, on the stabilities of ion coordination structures are also explored.

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Section: Resultsmentioning

confidence: 87%

Structural Transitions in Ion Coordination Driven by Changes in Competition for Ligand Binding

2008

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“…While the ionization states of titratable amino acids can shift from their bulk values in the protein environment, we assume all titratable amino acids to have ionization states equal to their default bulk values at a physiological pH of 7.4. Although there are numerous methods to compute p K a shifts, none are reliable in the context of the low resolution of the crystallographic data . Nevertheless, we note that this assumption can affect protein structure .…”

Section: Methodsmentioning

confidence: 93%

Effect of intrinsic and extrinsic factors on the simulated D-band length of type I collagen

et al. 2015

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A signature feature of collagen is its axial periodicity visible in TEM as alternating dark and light bands. In mature, type I collagen, this repeating unit, D, is 67 nm long. This periodicity reflects an underlying packing of constituent triple-helix polypeptide monomers wherein the dark bands represent gaps between axially adjacent monomers. This organization is visible distinctly in the microfibrillar model of collagen obtained from fiber diffraction. However, to date, no atomistic simulations of this diffraction model under zero-stress conditions have reported a preservation of this structural feature. Such a demonstration is important as it provides the baseline to infer response functions of physiological stimuli. In contrast, simulations predict a considerable shrinkage of the D-band (11-19%). Here we evaluate systemically the effect of several factors on D-band shrinkage. Using force fields employed in previous studies we find that irrespective of the temperature/pressure coupling algorithms, assumed salt concentration or hydration level, and whether or not the monomers are cross-linked, the D-band shrinks considerably. This shrinkage is associated with the bending and widening of individual monomers, but employing a force field whose backbone dihedral energy landscape matches more closely with our computed CCSD(T) values produces a small D-band shrinkage of < 3%. Since this force field also performs better against other experimental data, it appears that the large shrinkage observed in earlier simulations is a force-field artifact. The residual shrinkage could be due to the absence of certain atomic-level details, such as glycosylation sites, for which we do not yet have suitable data.

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“…The binding of Ca 2+ to multiple sites in a highly co-operative manner have been shown to facilitate protein responses to small changes in Ca 2+ concentration [42,43]. The high degree of co-operativity to Ca 2+ -binding showed by the CLR domains (Table 3) and the effects of these domains in the Ca 2+ -activation profile of chimaeric receptors are consistent with this idea.…”

Section: Discussionmentioning

confidence: 61%

Myoplasmic resting Ca2+ regulation by ryanodine receptors is under the control of a novel Ca2+-binding region of the receptor

Chen

Xue

Zou

et al. 2014

Biochemical Journal

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Passive SR (sarcoplasmic reticulum) Ca2+ leak through the RyR (ryanodine receptor) plays a critical role in the mechanisms that regulate [Ca2+]rest (intracellular resting myoplasmic free Ca2+ concentration) in muscle. This process appears to be isoform-specific as expression of either RyR1 or RyR3 confers on myotubes different [Ca2+]rest. Using chimaeric RyR3–RyR1 receptors expressed in dyspedic myotubes, we show that isoform-dependent regulation of [Ca2+]rest is primarily defined by a small region of the receptor encompassing amino acids 3770–4007 of RyR1 (amino acids 3620–3859 of RyR3) named as the CLR (Ca2+ leak regulatory) region. [Ca2+]rest regulation by the CLR region was associated with alteration of RyRs’ Ca2+-activation profile and changes in SR Ca2+-leak rates. Biochemical analysis using Tb3+-binding assays and intrinsic tryptophan fluorescence spectroscopy of purified CLR domains revealed that this determinant of RyRs holds a novel Ca2+-binding domain with conformational properties that are distinctive to each isoform. Our data suggest that the CLR region provides channels with unique functional properties that modulate the rate of passive SR Ca2+ leak and confer on RyR1 and RyR3 distinctive [Ca2+]rest regulatory properties. The identification of a new Ca2+-binding domain of RyRs with a key modulatory role in [Ca2+]rest regulation provides new insights into Ca2+-mediated regulation of RyRs.

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Ca²⁺ Activation of the cPLA₂ C2 Domain: Ordered Binding of Two Ca²⁺ Ions with Positive Cooperativity

Cited by 19 publications

References 49 publications

Structural Transitions in Ion Coordination Driven by Changes in Competition for Ligand Binding

Structural Transitions in Ion Coordination Driven by Changes in Competition for Ligand Binding

Effect of intrinsic and extrinsic factors on the simulated D-band length of type I collagen

Myoplasmic resting Ca2+ regulation by ryanodine receptors is under the control of a novel Ca2+-binding region of the receptor

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