A Photocontrolled β‐Hairpin Peptide

Dong, Shouliang; Löweneck, Markus; Schrader, Tobias E.; Schreier, Wolfgang; Zinth, Wolfgang; Moröder, Luis; Renner, Christian

doi:10.1002/chem.200500986

Cited by 107 publications

(122 citation statements)

References 35 publications

(14 reference statements)

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“…In the context of peptides, cis-AMPP has been shown to be a type I′ β-hairpin backbone peptidomimetic, whereas trans-AMPP lies in a planar conformation ( Figure 1B). 35 We hypothesized that, in the context of the Aβ42 peptide, the trans-azobenzene conformer would reduce selfassembly propensity (rate, thermodynamic stability of fibrils), while the cis-conformer would promote β-turn formation resulting in accelerated fibrillization. The position of the AMPP turn was chosen based on models proposed by Tycko and Smith, which place the turn between a D23/K28 salt bridge.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…16,17,22 NMR analysis of AMPPcontaining peptides by Dong et al has shown that the trans-AMPP moiety in the context of a Trp zipper can form a nonhairpin turn. 35 This implies that β-hairpin formation is not a strict prerequisite for fibril nucleation and that formation of a nonhairpin turn is sufficient to nucleate fibrillogenesis. That trans AMPP facilitates the formation of nonhairpin turns in Aβ is consistent with the spectroscopic data obtained herein, which correlates to solid-state NMR models of Aβ40 proposed by Tycko and co-workers that predict a nonhairpin turn within the putative turn region.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…36−38 AMPP can be selectively photoisomerized into cis or trans conformations; the cis conformer has been shown to nucleate β-hairpin turns in the context of peptides. 35 We hypothesized that nucleating the turn in Aβ42 using the AMPP photoswitch would nucleate fibrillization. We conjectured that, in the trans-conformation, the turn region would lie in an extended conformation that precludes efficient self-assembly.…”

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confidence: 99%

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An Azobenzene Photoswitch Sheds Light on Turn Nucleation in Amyloid-β Self-Assembly

Doran

Anderson

Latchney

et al. 2012

ACS Chem. Neurosci.

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Amyloid-β (Aβ) self-assembly into cross-β amyloid fibrils is implicated in a causative role in Alzheimer's disease pathology. Uncertainties persist regarding the mechanisms of amyloid selfassembly and the role of metastable prefibrillar aggregates. Aβ fibrils feature a sheet-turn-sheet motif in the constituent β-strands; as such, turn nucleation has been proposed as a rate-limiting step in the selfassembly pathway. Herein, we report the use of an azobenzene β-hairpin mimetic to study the role turn nucleation plays on Aβ selfassembly. [3-(3-Aminomethyl)phenylazo]phenylacetic acid (AMPP) was incorporated into the putative turn region of Aβ42 to elicit temporal control over Aβ42 turn nucleation; it was hypothesized that self-assembly would be favored in the cis-AMPP conformation if β-hairpin formation occurs during Aβ self-assembly and that the trans-AMPP conformer would display attenuated fibrillization propensity. It was unexpectedly observed that the trans-AMPP Aβ42 conformer forms fibrillar constructs that are similar in almost all characteristics, including cytotoxicity, to wild-type Aβ42. Conversely, the cis-AMPP Aβ42 congeners formed nonfibrillar, amorphous aggregates that exhibited no cytotoxicity. Additionally, cis-trans photoisomerization resulted in rapid formation of native-like amyloid fibrils and trans−cis conversion in the fibril state reduced the population of native-like fibrils. Thus, temporal photocontrol over Aβ turn conformation provides significant insight into Aβ self-assembly. Specifically, Aβ mutants that adopt stable β-turns form aggregate structures that are unable to enter folding pathways leading to cross-β fibrils and cytotoxic prefibrillar intermediates.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Results and Discussionmentioning

confidence: 99%

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confidence: 99%

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An Azobenzene Photoswitch Sheds Light on Turn Nucleation in Amyloid-β Self-Assembly

Doran

Anderson

Latchney

et al. 2012

ACS Chem. Neurosci.

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“…We and others (8)(9)(10) have recently focused on the design of photocontrolled ␤-hairpin peptides. To enable an ultrafast initiation of ␤-hairpin folding and unfolding the azobenzene derivative 3-(3-aminomethylphenylazo)phenylacetic acid (AMPP) was used as a reversible light switch (8,10), which, in the cis isomeric state, acts as ␤-turn mimetic (see Fig. 1A).…”

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confidence: 99%

Light-triggered β-hairpin folding and unfolding

Schrader

Schreier

Cordes

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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A light-switchable peptide is transformed with ultrashort pulses from a ␤-hairpin to an unfolded hydrophobic cluster and vice versa. The structural changes are monitored by mid-IR probing. Instantaneous normal mode analysis with a Hamiltonian combining density functional theory with molecular mechanics is used to interpret the absorption transients. Illumination of the ␤-hairpin state triggers an unfolding reaction that visits several intermediates and reaches the unfolded state within a few nanoseconds. In this unfolding reaction to the equilibrium hydrophobic cluster conformation, the system does not meet significant barriers on the free-energy surface. The reverse folding process takes much longer because it occurs on the time scale of 30 s. The folded state has a defined structure, and its formation requires an extended search for the correct hydrogen-bond pattern of the ␤-strand.density functional theory calculation ͉ peptide folding ͉ TrpZip2 ͉ ultrafast infrared spectroscopy F olding is a key process during the formation of a functional protein after the synthesis of its amino acid chain (1). During folding, the amino acid chains are rearranged in highly complex processes, for which a detailed understanding is still missing. Straightforward solutions of the folding problem are prevented by the high dimensionality of the protein conformational spaces and by the wide range of relevant time scales. Thus, for complexity reduction, one has to focus on typical protein substructures, which are small enough to be analyzed by present-day technology. With corresponding peptide model systems there is a chance to monitor the formation of secondary structures, to identify characteristic intermediate states of these folding dynamics, and to carry out realistic simulations on a molecular level. An interesting class of model systems are light-triggered peptides, within which the incorporation of a photoresponsive element can initiate structural changes.Among corresponding photoresponsive chromophores, azobenzene derivatives have become a popular choice when it comes to selecting a fast conformational trigger for peptide refolding, because their structure significantly changes on time scales of a few hundred femtoseconds after photoexcitation. Indeed, an azobenzene chromophore, used as a backbone element within cyclic peptides, was shown to induce large-scale conformational changes, whose dynamics could be monitored by visible (2) and IR (3) spectroscopy. Moreover, the experimental results clearly showed that the initial, strongly driven conformational changes of the peptide proceeded within a few picoseconds after the trigger event. Externally linked to an ␣-helix, azobenzene also was used for unfolding (4) and refolding (5) of an ␣-helical model peptide in the nanosecond to microsecond time range.A prominent secondary structure motif is the ␤-sheet, for which a ␤-hairpin represents a minimal model (6, 7). We and others (8-10) have recently focused on the design of photocontrolled ␤-hairpin peptides. To enable an ultrafa...

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“…A general feature of the disastrous conformational changes is a transition from native and "healthy" structures to |3-extended precursors of insoluble fibrils. We have now succeeded in designing, synthesizing and investigating a special Phairpin model [1], where the introduction of a femtosecond light switch in a (3-hairpin peptide allowed the observation of ultrafast structural changes -orders of magnitude faster than in previous experiments on P-structures. We show here that an optical trigger starts a series of picosecond conformational transitions of the pstructure (see Fig.…”

Section: Introductionmentioning

confidence: 99%

Ultrafast Unzipping of a Beta-Hairpin Peptide

Schrader¹,

Schreier²,

Koller³

et al. 2007

Ultrafast Phenomena XV

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Take-down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Abstract. Light induced switching of a beta-hairpin structure is investigated by femtosecond IR spectroscopy. While the unzipping process comprises ultrafast kinetics and is finished within 1 ns, the folding into the hairpin structure is a much slower process.

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A Photocontrolled β‐Hairpin Peptide

Cited by 107 publications

References 35 publications

An Azobenzene Photoswitch Sheds Light on Turn Nucleation in Amyloid-β Self-Assembly

An Azobenzene Photoswitch Sheds Light on Turn Nucleation in Amyloid-β Self-Assembly

Light-triggered β-hairpin folding and unfolding

Ultrafast Unzipping of a Beta-Hairpin Peptide

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