Katie Dunleavy scite author profile

Oxidation of methionine disrupts the structure and function of a range of proteins, but little is understood about the chemistry that underlies these perturbations. Using quantum mechanical calculations, we show that oxidation increases the strength of the methionine-aromatic interaction motif—a driving force for protein folding and protein-protein interaction—by 0.5 – 1.4 kcal/mol. We find that non-hydrogen bonded interactions between dimethyl sulfoxide (a methionine analog) and aromatic groups are enriched in both the Protein Data Bank and Cambridge Structural Database. Thermal denaturation and NMR experiments on model peptides demonstrate that oxidation of methionine stabilizes the interaction by 0.5–0.6 kcal/mol. We confirm the biological relevance of these findings through a combination of cell biology, electron paramagnetic resonance spectroscopy and molecular dynamics simulations on 1) calmodulin structure and dynamics and 2) lymphotoxin-α/TNFR1 binding. Thus, the methionine-aromatic motif is a determinant of protein structural and functional sensitivity to oxidative stress.

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Spin-label scanning reveals conformational sensitivity of the bound helical interfaces of IA<sub>3</sub>

Dunleavy¹,

Milshteyn²,

Sorrentino³

et al. 2018

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Randomly organized lipids and marginally stable proteins: A coupling of weak interactions to optimize membrane signaling

Rice

Mahling

Fealey

et al. 2014

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Eukaryotic lipids in a bilayer are dominated by weak cooperative interactions. These interactions impart highly dynamic and pliable properties to the membrane. C2 domain-containing proteins in the membrane also interact weakly and cooperatively giving rise to a high degree of conformational plasticity. We propose that this feature of weak energetics and plasticity shared by lipids and C2 domain-containing proteins enhance a cell's ability to transduce information across the membrane. We explored this hypothesis using information theory to assess the information storage capacity of model and mast cell membranes, as well as differential scanning calorimetry, carboxyfluorescein release assays, and tryptophan fluorescence to assess protein and membrane stability. The distribution of lipids in mast cell membranes encoded 5.6-5.8bits of information. More information resided in the acyl chains than the head groups and in the inner leaflet of the plasma membrane than the outer leaflet. When the lipid composition and information content of model membranes were varied, the associated C2 domains underwent large changes in stability and denaturation profile. The C2 domain-containing proteins are therefore acutely sensitive to the composition and information content of their associated lipids. Together, these findings suggest that the maximum flow of signaling information through the membrane and into the cell is optimized by the cooperation of near-random distributions of membrane lipids and proteins. This article is part of a Special Issue entitled: Interfacially Active Peptides and Proteins. Guest Editors: William C. Wimley and Kalina Hristova.

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Synaptotagmin I’s Intrinsically Disordered Region Interacts with Synaptic Vesicle Lipids and Exerts Allosteric Control over C2A

et al. 2016

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Synaptotagmin I (Syt I) is a vesicle-localized integral membrane protein that senses the calcium ion (Ca(2+)) influx to trigger fast synchronous release of neurotransmitter. How the cytosolic domains of Syt I allosterically communicate to propagate the Ca(2+) binding signal throughout the protein is not well understood. In particular, it is unclear whether the intrinsically disordered region (IDR) between Syt I's transmembrane helix and first C2 domain (C2A) plays an important role in allosteric modulation of Ca(2+) binding. Moreover, the structural propensity of this IDR with respect to membrane lipid composition is unknown. Using differential scanning and isothermal titration calorimetry, we found that inclusion of the IDR does indeed allosterically modulate Ca(2+) binding within the first C2 domain. Additionally through application of nuclear magnetic resonance, we found that Syt I's IDR interacts with membranes whose lipid composition mimics that of a synaptic vesicle. These findings not only indicate that Syt I's IDR plays a role in regulating Syt I's Ca(2+) sensing but also indicate the IDR is exquisitely sensitive to the underlying membrane lipids. The latter observation suggests the IDR is a key route for communication of lipid organization to the adjacent C2 domains.

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Uncovering Order within the Disorder: Redefining IA3's Intrinsically Disordered Properties

Dunleavy

Amaris

et al. 2020

Biophysical Journal

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We generated a panel of single-domain antibodies targeting selected epitopes within tau, using the 'cascade method'. Briefly, we designed complementary peptides targeting linear epitopes within the sequence of tau using a library of beta-sheet fragments from the protein data bank. We then grafted each peptide into the CDR3 loop of a V H human scaffold. Using this approach, we produced a library of fourteen antibodies covering systematically the length of tau. We will use these antibodies to understand which epitopes are specifically exposed in toxic tau aggregates. In particular, we will employ them in superresolved imaging, such as DNA points accumulation for imaging in nanoscale topography (DNA PAINT), of protein aggregates. DNA PAINT enables visualization of structures with resolutions below the diffraction limit using short dye-labelled oligonucleotide probes. Transient binding of a dye-labelled 'imager strand' to a 'docking strand' (DS), which we conjugated to the C-terminus of DesAbs creates a blinking effect. Hence, a highly resolved image can be reconstructed from plotting the measured positions of the hydrolyzed DNA state. Using this technique to image protein aggregates in human cerebrospinal fluid and serum will provide novel insights into the composition, structure, size and number of aggregates present in those samples.

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Katie Dunleavy

Oxidation increases the strength of the methionine-aromatic interaction

Spin-label scanning reveals conformational sensitivity of the bound helical interfaces of IA<sub>3</sub>

Randomly organized lipids and marginally stable proteins: A coupling of weak interactions to optimize membrane signaling

Synaptotagmin I’s Intrinsically Disordered Region Interacts with Synaptic Vesicle Lipids and Exerts Allosteric Control over C2A

Uncovering Order within the Disorder: Redefining IA3's Intrinsically Disordered Properties

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