Effective synthesis, development and application of a highly fluorescent cyanine dye for antibody conjugation and microscopy imaging.

An asymmetric cyanine-type fluorescent dye was designed and synthesized via a versatile, multi-step process, aiming to conjugate with an Her2+ receptor specific antibody by an azide-alkyne click reaction. The aromaticity and the excitation and relaxation energetics of the fluorophore were characterized by computational methods. The synthesized dye exhibited excellent fluorescence properties for confocal microscopy, offering efficient applicability in in vitro imaging due to its merits such as a high molar absorption coefficient (36 816 M-1 cm-1), excellent brightness, optimal wavelength (627 nm), larger Stokes shift (26 nm) and appropriate photostability compared to cyanines. The conjugated cyanine-trastuzumab was constructed via an effective, metal-free, strain-promoted azide-alkyne click reaction leading to a regulated number of dyes being conjugated. This novel cyanine-labelled antibody was successfully applied for in vitro confocal imaging and flow cytometry of Her2+ tumor cells.

Computational Elucidation of the Solvent-Dependent Addition of 4-Hydroxy-2-nonenal (HNE) to Cysteine and Cysteinate Residues.

The lipid peroxidation end product, 4-hydroxy-2-nonenal (HNE), is a secondary mediator of oxidative stress due to its strong ability to form adducts to the side chains of lysine, histidine, and cysteine residues (Cys) at increasing reactivities. This reaction can take place in various cellular environments and may be dependent on solvent. Moreover, approximately 10% of cysteine residues within the cells exist as the negatively charged cysteinate, which may also have a distinct reactivity toward HNE. In this study, quantum chemical calculations are used to investigate the reactivity of HNE toward Cys and cysteinate in three distinct solvent environments to mimic the aqueous, polar, and hydrophobic regions within the cell. Water enhances the reactivity of HNE to cysteine compared to that of the polar and hydrophobic solvents, and the reactivity of HNE is further augmented when Cys is first ionized to cysteinate. This is also confirmed by the transition state rate constant calculations. This study reveals the role of solvent polarity in these reactions and how cysteinate can account for the seemingly high reactivity of HNE toward Cys compared to other amino acid residues and demonstrates how a strong nucleophile can enhance the reactivity of an antioxidant analogue of the Cys residue.

Ring-Opening Metathesis Polymerization and Related Olefin Metathesis Reactions in Benzotrifluoride as an Environmentally Advantageous Medium.

A tremendous number of solvents, either as liquids or vapors, contaminate the environment on a daily basis worldwide. Olefin metathesis, which has been widely used as high-yielding protocols for ring-opening metathesis polymerization (ROMP), ring-closing metathesis (RCM), and isomerization reactions, is typically performed in toxic and volatile solvents such as dichloromethane. In this study, the results of our systematic experiments with the Grubbs G1, G2, and Hoveyda-Grubbs HG2 catalysts proved that benzotrifluoride (BTF) can replace dichloromethane (DCM) in these reactions, providing high yields and similar or even higher reaction rates in certain cases. The ROMP of norbornene resulted not only in high yields but also in polynorbornenes with a high molecular weight at low catalyst loadings. Ring-closing metathesis (RCM) experiments proved that, with the exception of the G1 catalyst, RCM occurs with similar high efficiencies in BTF as in DCM. It was found that isomerization of (Z)-but-2-ene-1,4-diyl diacetate with the G2 and HG2 catalysts proceeds at significantly higher initial rates in BTF than in DCM, leading to rapid isomerization with high yields in a short time. Overall, BTF is a suitable solvent for olefin metathesis, such as polymer syntheses by ROMP and the ring-closing and isomerization reactions.

The impact of the glycan headgroup on the nanoscopic segregation of gangliosides.

Gangliosides form an important class of receptor lipids containing a large oligosaccharide headgroup whose ability to self-organize within lipid membranes results in the formation of nanoscopic platforms. Despite their biological importance, the molecular basis for the nanoscopic segregation of gangliosides is not clear. In this work, we investigated the role of the ganglioside headgroup on the nanoscale organization of gangliosides. We studied the effect of the reduction in the number of sugar units of the ganglioside oligosaccharide chain on the ability of gangliosides GM1, GM2, and GM3 to spontaneously self-organize into lipid nanodomains. To reach nanoscopic resolution and to identify molecular forces that drive ganglioside segregation, we combined an experimental technique, Förster resonance energy transfer analyzed by Monte-Carlo simulations offering high lateral and trans-bilayer resolution with molecular dynamics simulations. We show that the ganglioside headgroup plays a key role in ganglioside self-assembly despite the negative charge of the sialic acid group. The nanodomains range from 7 to 120 nm in radius and are mostly composed of the surrounding bulk lipids, with gangliosides being a minor component of the nanodomains. The interactions between gangliosides are dominated by the hydrogen bonding network between the headgroups, which facilitates ganglioside clustering. The N-acetylgalactosamine sugar moiety of GM2, however, seems to impair the stability of these clusters by disrupting hydrogen bonding of neighboring sugars, which is in agreement with a broad size distribution of GM2 nanodomains. The simulations suggest that the formation of nanodomains is likely accompanied by several conformational changes in the gangliosides, which, however, have little impact on the solvent exposure of these receptor groups. Overall, this work identifies the key physicochemical factors that drive nanoscopic segregation of gangliosides.

Amyloid-ß peptide dimers undergo a random coil to ß-sheet transition in the aqueous phase but not at the neuronal membrane.

Mounting evidence suggests that the neuronal cell membrane is the main site of oligomer-mediated neuronal toxicity of amyloid-ß peptides in Alzheimer's disease. To gain a detailed understanding of the mutual interference of amyloid-ß oligomers and the neuronal membrane, we carried out microseconds of all-atom molecular dynamics (MD) simulations on the dimerization of amyloid-ß (Aß)42 in the aqueous phase and in the presence of a lipid bilayer mimicking the in vivo composition of neuronal membranes. The dimerization in solution is characterized by a random coil to ß-sheet transition that seems on pathway to amyloid aggregation, while the interactions with the neuronal membrane decrease the order of the Aß42 dimer by attenuating its propensity to form a ß-sheet structure. The main lipid interaction partners of Aß42 are the surface-exposed sugar groups of the gangliosides GM1. As the neurotoxic activity of amyloid oligomers increases with oligomer order, these results suggest that GM1 is neuroprotective against Aß-mediated toxicity.

Role of Oxidized Gly25, Gly29, and Gly33 Residues on the Interactions of Aß1-42 with Lipid Membranes.

Oxidative stress is known to play an important role in the pathogenesis of Alzheimer's disease. Moreover, it is becoming increasingly evident that the plasma membrane of neurons plays a role in modulating the aggregation and toxicity of Alzheimer's amyloid-ß peptide (Aß). In this study, the combined and interdependent effects of oxidation and membrane interactions on the 42 residues long Aß isoform are investigated using molecular simulations. Hamiltonian replica exchange molecular dynamics simulations are utilized to elucidate the impact of selected oxidized glycine residues of Aß42 on the interactions of the peptide with a model membrane comprised of 70% POPC, 25% cholesterol, and 5% of the ganglioside GM1. The main findings are that, independent of the oxidation state, Aß prefers binding to GM1 over POPC, which is further enhanced by the oxidation of Gly29 and Gly33 and reduced the formation of ß-sheet. Our results suggest that the differences observed in Aß42 conformations and its interaction with a lipid bilayer upon oxidation originate from the position of the oxidized Gly residue with respect to the hydrophobic sequence of Aß42 involving the Gly29-XXX-Gly33-XXX-Gly37 motif and from specific interactions between the peptide and the terminal sugar groups of GM1.

Force Field Comparison of GM1 in a DOPC Bilayer Validated with AFM and FRET Experiments.

The great physiological relevance of glycolipids is being increasingly recognized, and glycolipid interactions have been shown to be central to cell-cell recognition, neuronal plasticity, protein-ligand recognition, and other important processes. However, detailed molecular-level understanding of these processes remains to be fully resolved. Molecular dynamics simulations could reveal the details of the glycolipid interactions, but the results may be influenced by the choice of the employed force field. Here, we have compared the behavior and properties of GM1, a common, biologically important glycolipid, using the CHARMM36, OPLS, GROMOS, and Amber99-GLYCAM06 (in bilayers comprising SLIPIDS and LIPID14 lipids) force fields in bilayers comprising 1,2-dioleoyl-sn-glycero-3-phosphocholine lipids and compared the results to atomic force microscopy and fluorescence resonance energy transfer experiments. We found discrepancies within the GM1 behavior displayed between the investigated force fields. Based on a direct comparison with complementary experimental results derived from fluorescence and AFM measurements, we recommend using the Amber99-GLYCAM force field in bilayers comprising LIPID14 or SLIPIDS lipids followed by CHARMM36 and OPLS force fields in simulations. The GROMOS force field is not recommended for reproducing the properties of the GM1 head group.

Effects of in vivo conditions on amyloid aggregation.

One of the grand challenges of biophysical chemistry is to understand the principles that govern protein misfolding and aggregation, which is a highly complex process that is sensitive to initial conditions, operates on a huge range of length- and timescales, and has products that range from protein dimers to macroscopic amyloid fibrils. Aberrant aggregation is associated with more than 25 diseases, which include Alzheimer's, Parkinson's, Huntington's, and type II diabetes. Amyloid aggregation has been extensively studied in the test tube, therefore under conditions that are far from physiological relevance. Hence, there is dire need to extend these investigations to in vivo conditions where amyloid formation is affected by a myriad of biochemical interactions. As a hallmark of neurodegenerative diseases, these interactions need to be understood in detail to develop novel therapeutic interventions, as millions of people globally suffer from neurodegenerative disorders and type II diabetes. The aim of this review is to document the progress in the research on amyloid formation from a physicochemical perspective with a special focus on the physiological factors influencing the aggregation of the amyloid-ß peptide, the islet amyloid polypeptide, α-synuclein, and the hungingtin protein.

Aß under stress: the effects of acidosis, Cu2+-binding, and oxidation on amyloid ß-peptide dimers.

In light of the high affinity of Cu2+ for Alzheimer's Aß1-42 and its ability to subsequently catalyze the formation of radicals, we examine the effects of Cu2+ binding, Aß oxidation, and an acidic environment on the conformational dynamics of the smallest Aß1-42 oligomer, the Aß1-42 dimer. Transition networks calculated from Hamiltonian replica exchange molecular dynamics (H-REMD) simulations reveal that the decreased pH considerably increased the ß-sheet content, whereas Cu2+ binding increased the exposed hydrophobic surface area, both of which can contribute to an increased oligomerization propensity and toxicity.

Physiologically-relevant levels of sphingomyelin, but not GM1, induces a ß-sheet-rich structure in the amyloid-ß(1-42) monomer.

To resolve the contribution of ceramide-containing lipids to the aggregation of the amyloid-ß protein into ß-sheet rich toxic oligomers, we employed molecular dynamics simulations to study the effect of cholesterol-containing bilayers comprised of POPC (70% POPC, and 30% cholesterol) and physiologically relevant concentrations of sphingomyelin (SM) (30% SM, 40% POPC, and 30% cholesterol), and the GM1 ganglioside (5% GM1, 70% POPC, and 25% cholesterol). The increased bilayer rigidity provided by SM (and to a lesser degree, GM1) reduced the interactions between the SM-enriched bilayer and the N-terminus of Aß42 (and also residues Ser26, Asn27, and Lys28), which facilitated the formation of a ß-sheet in the normally disordered N-terminal region. Aß42 remained anchored to the SM-enriched bilayer through hydrogen bonds with the side chain of Arg5. With ß-sheets in the at the N and C termini, the structure of Aß42 in the sphingomyelin-enriched bilayer most resembles ß-sheet-rich structures found in higher-ordered Aß fibrils. Conversely, when bound to a bilayer comprised of 5% GM1, the conformation remained similar to that observed in the absence of GM1, with Aß42 only making contact with one or two GM1 molecules. This article is part of a Special Issue entitled: Protein Aggregation and Misfolding at the Cell Membrane Interface edited by Ayyalusamy Ramamoorthy.

Cholesterol Protects the Oxidized Lipid Bilayer from Water Injury: An All-Atom Molecular Dynamics Study.

In an effort to delineate how cholesterol protects membrane structure under oxidative stress conditions, we monitored the changes to the structure of lipid bilayers comprising 30 mol% cholesterol and an increasing concentration of Class B oxidized 1-palmitoyl-2-oleoylphosphatidylcholine (POPC) glycerophospholipids, namely, 1-palmitoyl-2-(9'-oxo-nonanoyl)-sn-glycero-3-phosphocholine (PoxnoPC), and 1-palmitoyl-2-azelaoyl-sn-glycero-3-phosphocholine (PazePC), using atomistic molecular dynamics simulations. Increasing the content of oxidized phospholipids (oxPLs) from 0 to 60 mol% oxPL resulted in a characteristic reduction in bilayer thickness and increase in area per lipid, thereby increasing the exposure of the membrane hydrophobic region to water. However, cholesterol was observed to help reduce water injury by moving into the bilayer core and forming more hydrogen bonds with the oxPLs. Cholesterol also resists altering its tilt angle, helping to maintain membrane integrity. Water that enters the 1-nm-thick core region remains part of the bulk water on either side of the bilayer, with relatively few water molecules able to traverse through the bilayer. In cholesterol-rich membranes, the bilayer does not form pores at concentrations of 60 mol% oxPL as was shown in previous simulations in the absence of cholesterol.

Protein Stability and Unfolding Following Glycine Radical Formation.

Glycine (Gly) residues are particularly susceptible to hydrogen abstraction; which results in the formation of the capto-dative stabilized Cα-centered Gly radical (GLR) on the protein backbone. We examined the effect of GLR formation on the structure of the Trp cage; tryptophan zipper; and the villin headpiece; three fast-folding and stable miniproteins; using all-atom (OPLS-AA) molecular dynamics simulations. Radicalization changes the conformation of the GLR residue and affects both neighboring residues but did not affect the stability of the Trp zipper. The stability of helices away from the radical center in villin were also affected by radicalization; and GLR in place of Gly15 caused the Trp cage to unfold within 1 µs. These results provide new evidence on the destabilizing effects of protein oxidation by reactive oxygen species.

Radical Formation Initiates Solvent-Dependent Unfolding and ß-sheet Formation in a Model Helical Peptide.

We examined the effects of Cα-centered radical formation on the stability of a model helical peptide, N-Ac-KK(AL)10KK-NH2. Three, 100 ns molecular dynamics simulations using the OPLS-AA force field were carried out on each α-helical peptide in six distinct binary TIP4P water/2,2,2-trifluoroethanol (TFE) mixtures. The α-helicity was at a maximum in 20% TFE, which was inversely proportional to the number of H-bonds between water molecules and the peptide backbone. The radial distribution of TFE around the peptide backbone was highest in 20% TFE, which enhanced helix stability. The Cα-centered radical initiated the formation of a turn within 5 ns, which was a smaller kink at high TFE concentrations, and a loop at lower TFE concentrations. The highest helicity of the peptide radical was measured in 100% TFE. The formation of hydrogen bonds between the peptide backbone and water destabilized the helix, whereas the clustering of TFE molecules around the radical center stabilized the helix. Following radical termination, the once helical structure converted to a ß-sheet rich state in 100% water only, and this transition did not occur in the nonradical control peptide. This study gives evidence on how the formation of peptide radicals can initiate α-helical to ß-sheet transitions under oxidative stress conditions.

An Account of Amyloid Oligomers: Facts and Figures Obtained from Experiments and Simulations.

The deposition of amyloid in brain tissue in the context of neurodegenerative diseases involves the formation of intermediate species-termed oligomers-of lower molecular mass and with structures that deviate from those of mature amyloid fibrils. Because these oligomers are thought to be primarily responsible for the subsequent disease pathogenesis, the elucidation of their structure is of enormous interest. Nevertheless, because of the high aggregation propensity and the polydispersity of oligomeric species formed by the proteins or peptides in question, the preparation of appropriate samples for high-resolution structural methods has proven to be rather difficult. This is why theoretical approaches have been of particular importance in gaining insights into possible oligomeric structures for some time. Only recently has it been possible to achieve some progress with regard to the experimentally based structural characterization of defined oligomeric species. Here we discuss how theory and experiment are used to determine oligomer structures and what can be done to improve the integration of the two disciplines.

Thyroid hormone-dependent development in Xenopus laevis: a sensitive screen of thyroid hormone signaling disruption by municipal wastewater treatment plant effluent.

Because thyroid hormones (THs) are conserved modulators of development and physiology, identification of compounds adversely affecting TH signaling is critical to human and wildlife health. Anurans are an established model for studying disruption of TH signaling because metamorphosis is dependent upon the thyroid system. In order to strengthen this model and identify new gene transcript biomarkers for TH disruption, we performed DNA microarray analysis of Xenopus laevis tadpole tail transcriptomes following treatment with triiodothyronine (T(3)). Comparison of these results with previous studies in frogs and mammals identified 36 gene transcripts that were TH-sensitive across clades. We then tested molecular biomarkers for sensitivity to disruption by exposure to wastewater effluent (WWE). X. laevis tadpoles, exposed to WWE from embryo through metamorphosis, exhibited an increased developmental rate compared to controls. Cultured tadpole tails showed dramatic increases in levels of four TH-sensitive gene transcripts (thyroid hormone receptor ß (TRß), deiodinase type II (DIO2), and corticotropin releasing hormone binding protein (CRHBP), fibroblast activation protein α (FAPα)) when exposed to T(3) and WWE extracts. TRß, DIO2, and CRHBP were identified as TH sensitive in other studies, while FAPα mRNA transcripts were highly TH sensitive in our array. The results validate the array and demonstrate TH-disrupting activity by WWE. Our findings demonstrate the usefulness of cross-clade analysis for identification of gene transcripts that provide sensitivity to endocrine disruption. Further, the results suggest that development is disrupted by exposure to complex mixes of compounds found in WWE possibly through interference with TH signaling.

Conformation-dependent ˙OH/H2O2 hydrogen abstraction reaction cycles of Gly and Ala residues: a comparative theoretical study.

To determine if (•)OH can initiate the unfolding of an amino acid residue, the elementary reaction coordinates of H abstraction by (•)OH different conformations (ß(L), γ(L), γ(D), α(L), and α(D)) of Gly and Ala dimethyl amides were computed using first-principles quantum computations. The MPWKCIS1K/6-311++G(3df,2p)//BHandHLYP/6-311+G(d,p) level of theory was selected after different combinations of functionals and basis sets were compared. The structures of Gly and Ala in the elementary reaction steps were compared to the conformers of the Gly, Gly(•), Ala, and Ala(•) structures in the absence of (•)OH/H(2)O, which were identified by optimizing the minima of the respective potential energy surfaces. A dramatic change in conformation is observed in the Gly and Ala conformers after conversion to Gly(•) and Ala(•), respectively, and this change can be monitored along the minimal energy pathway. The ß(L) conformer of Gly (-0.3 kJ mol(-1)) and Ala (-1.6 kJ mol(-1)) form the lowest-lying transition states in the reaction with (•)OH, whereas the side chain of Ala strongly destabilizes the α conformers compared to the γ conformers, which could cause the lower reactivity shown in Ala. This effect shown in Ala could affect the abstraction of hydrogen from Ala and the other chiral amino acid residues in the helices. The energy of subsequent hydrogen abstraction reactions between Ala(•) and Gly(•) and H(2)O(2) remains approximately 90 kJ mol(-1) below the entrance level of the (•)OH reaction, indicating that the (•)OH radical can initiate an α to ß transition in an amino acid residue if a molecule such as H(2)O(2) can provide the hydrogen atom necessary to re-form Gly and Ala. This work delineates the mechanism of the rapid (•)OH-initiated unfolding of peptides and proteins which has been proposed in Alzheimer's and other peptide misfolding diseases involving amyloidogenic peptides.

The Effect of Newly Developed OPLS-AA Alanyl Radical Parameters on Peptide Secondary Structure.

Recent studies using ab initio calculations have shown that Cα-centered radical formation by H-abstraction from the backbone of peptide residues has dramatic effects on peptide structure and have suggested that this reaction may contribute to the protein misfolding observed in Alzheimer's and Parkinson's diseases. To enable the effects of Cα-centered radicals to be studied in longer peptides and proteins over longer time intervals, force-field parameters for the Cα-centered Ala radical were developed for use with the OPLS force field by minimizing the sum of squares deviation between the quantum chemical and OPLS-AA energy hypersurfaces. These parameters were used to determine the effect of the Cα-centered Ala radical on the structure of a hepta-alanyl peptide in molecular dynamics (MD) simulations. A negligible sum-of-squares energy deviation was observed in the stretching parameters, and the newly developed OPLS-AA torsional parameters showed a good agreement with the LMP2/cc-pVTZ(-f) hypersurface. The parametrization also demonstrated that derived force-field bond length and bond angle parameters can deviate from the quantum chemical equilibrium values, and that the improper torsional parameters should be developed explicitly with respect to the coupled torsional parameters. The MD simulations showed planar conformations of the Cα-containing residue (Alr) are preferred and these conformations increase the formation of γ-, α-, and π-turn structures depending on the position in the turn occupied by the Alr residue. Higher-ordered structures are destabilized by Alr except when this residue occupies position "i + 1" of the 310-helix. These results offer new insight into the protein-misfolding mechanisms initiated by H-abstraction from the Cα of peptide and protein residues.

Evaluation of medication list completeness, safety, and annotations.

Clinical documents frequently contain a list of a patient's medications. Missing information about the dosage, route, or frequency of a medication impairs clinical communication and may harm patients. We examined 253 medication lists. There were 181 lists (72%) with at least one medication missing a dose, route, or frequency. Missing information was judged to be potentially harmful in 47 of the lists (19% of 253) by three physician reviewers (kappa=0.69). We also observed that many lists contained additional information included as annotations, prompting a secondary thematic analysis of the annotations. Fifty-five of the 253 lists (22%) contained one or more annotations. The most frequent types of annotations were comments about the patient's medical history, the clinician's treatment plan changes, and the patient's adherence to a medication. Future development of electronic medication reconciliation tools to improve medication list completeness should also support annotating the medication list in a flexible manner.

Quantum chemical analysis of the unfolding of a penta-glycyl 3(10)-helix initiated by HO(●), HO2(●), and O2(-●).

In this study, the thermodynamic functions of hydrogen abstraction from the C(α) and amide nitrogen of Gly(3) in a homo-pentapeptide (N-Ac-GGGGG-NH(2); G5) by HO(●), HO(2)(●), and O(2)(-●) were computed using the Becke three-parameter Lee-Yang-Parr (B3LYP) density functional. The thermodynamic functions, standard enthalpy (ΔH°), Gibbs free energy (ΔG°), and entropy (ΔS°), of these reactions were computed with G5 in the 3(10)-helical (G5(Hel)) and fully-extended (G5(Ext)) conformations at the B3LYP/6-31G(d) and B3LYP/6-311+G(d,p) levels of theory, both in the gas phase and using the conductor-like polarizable continuum model implicit water model. H abstraction is more favorable at the C(α) than at the amide nitrogen. The secondary structure of G5 affects the bond dissociation energy of the H-C(α), but has a negligible effect on the dissociation energy of the H-N bond. The HO(●) radical is the strongest hydrogen abstractor, followed by HO(2)(●), and finally O(2)(-●). The secondary structure elements, such as H-bonds in the 3(10)-helix, protect the peptide from radical attack by disabling the potential electron delocalization at the C(α), which is possible when G5 is in the extended conformation. The unfolding of the peptide radicals is more favorable than the unfolding of G5(Hel); however, only the HO(●) can initiate the unfolding of G5(Hel) and the formation of G5(Ext)(●). These results are relevant to peptides that are prone to undergoing transitions from helical structures to ß-sheets in the cellular condition known as "oxidative stress" and the results are discussed in this context.

Quantum chemical analysis of the unfolding of a penta-alanyl 3(10)-helix initiated by HO(•), HO2(•) and O2(-•).

In order to elucidate the mechanisms of radical-initiated unfolding of a helix, the thermodynamic functions of hydrogen abstraction from the C(α), C(ß), and amide nitrogen of Ala(3) in a homopeptapeptide (N-Ac-AAAAA-NH(2); A5) by HO(•), HO(2)(•), and O(2)(-•) were computed using the B3LYP density functional. The thermodynamic functions, standard enthalpy (ΔH(o)), Gibbs free energy (ΔG(o)), and entropy (ΔS(o)), of the reactants and products of these reactions were computed with A5 in the 3(10)-helical (A5(Hel)) and fully extended (A5(Ext)) conformations at the B3LYP/6-31G(d) and B3LYP/6-311+G(d,p) levels of theory, both in the gas phase and using the C-PCM implicit water model. With quantum chemical calculations, we have shown that H abstraction is the most favorable at the C(α), followed by the C(ß), then amide N in a model helix. The secondary structure has a strong influence on the bond dissociation energy of the H-C(α), but a negligible effect on the dissociation energy of the H-CH(2) and H-N bonds. The HO(•) radical is the strongest hydrogen abstractor, followed by HO(2)(•) and finally O(2)(-•). More importantly, secondary structure elements, such as H-bonds in the 3(10)-helix, protect the peptide from radical attack by hindering the potential electron delocalization at the C(α) when the peptide is in the extended conformation. We also show that he unfolding of the A5 peptide radicals have a significantly higher propensity to unfold than the closed shell A5 peptide and confirm that only the HO(•) can initiate the unfolding of A5(Hel) and the formation of A5(Ext)(•). By comparing the structures, energies, and thermodynamic functions of A5 and its radical derivatives, we have shown how free radicals can initiate the unfolding of helical structures to ß-sheets in the cellular condition known as oxidative stress.