Mechanism and uses of a membrane peptide that targets tumors and other acidic tissues
            <i>in vivo</i>

Andreev, Oleg A.; Dupuy, Allison D.; Segala, Michael; Sandugu, Srikanth; Serra, David A.; Chichester, C. O.; Engelman, Donald M.; Reshetnyak, Yana K.

doi:10.1073/pnas.0702439104

Cited by 271 publications

(345 citation statements)

References 28 publications

(32 reference statements)

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“…In contrast to previously studied amphipathic peptides, it does not aggregate, form helical structure on the surface of a membrane, or induce pore formation (6)(7)(8)(9)12). Folding (formation of a transmembrane helix) accompanies insertion of the peptide into the lipid bilayer.…”

Section: Resultsmentioning

confidence: 89%

“…pHLIP contains two tryptophan residues having fluorescence that reports the attachment of the peptide to the membrane surface and the insertion of the peptide across the lipid bilayer as an ␣-helix (6,8,9). We chose 100-nm large unilamellar vesicles (LUV) containing palmitoyloleoylphosphatidylcholine (POPC) lipids with zwitterionic head groups to minimize any electrostatic component of the pHLIP interaction and to study peptide-membrane interactions over a wider range of temperatures than was possible in earlier work with dimyristoylphosphatidylcholine (DMPC) (6).…”

Section: Resultsmentioning

confidence: 99%

“…The number of protons involved in the process of protonation of pHLIP is Ϸ1.5-1.8. Previously, we demonstrated by mutation that the two Asp residues located in the transmembrane part of pHLIP are involved in protonation and peptide insertion/folding (8). Recognizing the nature of the hydrophobic gradient, partial titration of one of the Asp groups could account for the fractional number.…”

Section: (For 37°c) (B)mentioning

confidence: 99%

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Energetics of peptide (pHLIP) binding to and folding across a lipid bilayer membrane

Reshetnyak

Andreev

Segala

et al. 2008

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

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166

180

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The pH low-insertion peptide (pHLIP) serves as a model system for peptide insertion and folding across a lipid bilayer. It has three general states: (I) soluble in water or (II) bound to the surface of a lipid bilayer as an unstructured monomer, and (III) inserted across the bilayer as a monomeric ␣-helix. We used fluorescence spectroscopy and isothermal titration calorimetry to study the interactions of pHLIP with a palmitoyloleoylphosphatidylcholine (POPC) lipid bilayer and to calculate the transition energies between states. We found that the Gibbs free energy of binding to a POPC surface at low pHLIP concentration (state I-state II transition) at 37°C is approximately ؊7 kcal/mol near neutral pH and that the free energy of insertion and folding across a lipid bilayer at low pH (state II-state III transition) is nearly ؊2 kcal/mol. We discuss a number of related thermodynamic parameters from our measurements. Besides its fundamental interest as a model system for the study of membrane protein folding, pHLIP has utility as an agent to target diseased tissues and translocate molecules through the membrane into the cytoplasm of cells in environments with elevated levels of extracellular acidity, as in cancer and inflammation. The results give the amount of energy that might be used to move cargo molecules across a membrane.thermodynamics ͉ drug delivery ͉ imaging ͉ membrane protein T he folding of helical membrane proteins can be conceptualized in terms of distinct steps: (i) peptide insertion and folding to form independently stable helices across a lipid bilayer, (ii) helix association to form a helix bundle intermediate, and (iii) further rearrangements of protein structure and/or binding of prosthetic groups to achieve a functional state (1). Insertion of most membrane proteins is facilitated in vivo by complex molecular machines, such as the translocon, which assist in placing hydrophobic sequences across the bilayer (2). In contrast to more hydrophobic sequences, moderately polar transmembrane domains of Cterminally-anchored proteins can postranslationally translocate themselves into membranes in a translocon-defective yeast strain (3, 4), seeking the free-energy minimum (5). Thus, insertion of a disordered peptide in aqueous solution to form a transbilayer ␣-helix is accompanied by a release of energy, so thermodynamic studies of the interaction of proteins and peptides with a lipid bilayer can provide insights regarding folding. However, such studies are significantly complicated by the poor solubility of membrane peptides, which has made it difficult to separate the contributions of peptide interactions with a lipid bilayer from self-interactions and aggregation.We have been studying a useful system for measurement of the thermodynamics and kinetics of peptide insertion and folding across a lipid bilayer. It is based on the pH low-insertion peptide (pHLIP), which has three major states: (I) soluble in water in an unstructured, monomeric state, (II) bound to the surface of a lipid bilayer in an unstructu...

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Section: Resultsmentioning

confidence: 89%

Section: Resultsmentioning

confidence: 99%

Section: (For 37°c) (B)mentioning

confidence: 99%

See 1 more Smart Citation

Energetics of peptide (pHLIP) binding to and folding across a lipid bilayer membrane

Reshetnyak

Andreev

Segala

et al. 2008

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

Self Cite

166

180

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“…The pKa of the transition from state II to state III is 6.0 (6,8). The insertion is driven by the protonation of two Asp residues in the transmembrane region, leading to an increase of hydrophobicity that results in the folding of the peptide across a membrane (9). Increasing the pH promotes the unfolding and exit of the peptide from the core of the lipid bilayer.…”

mentioning

confidence: 99%

pH (low) insertion peptide (pHLIP) inserts across a lipid bilayer as a helix and exits by a different path

Andreev

Karabadzhak

Weerakkody

et al. 2010

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

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146

197

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What are the molecular events that occur when a peptide inserts across a membrane or exits from it? Using the pH-triggered insertion of the pH low insertion peptide to enable kinetic analysis, we show that insertion occurs in several steps, with rapid (0.1 sec) interfacial helix formation, followed by a much slower (100 sec) insertion pathway to give a transmembrane helix. The reverse process of unfolding and peptide exit from the bilayer core, which can be induced by a rapid rise of the pH from acidic to basic, proceeds approximately 400 times faster than folding/insertion and through different intermediate states. In the exit pathway, the helix-coil transition is initiated while the polypeptide is still inside the membrane. The peptide starts to exit when about 30% of the helix is unfolded, and continues a rapid exit as it unfolds inside the membrane. These insights may guide understanding of membrane protein folding/unfolding and the design of medically useful peptides for imaging and drug delivery.folding kinetics | helix formation | lipid-peptide interaction | membranes | transmembrane helix

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“…Second, the charge and hydrophobicity of surface ligands covering the QD can tune the degree of cell and tissue binding. We expect this phenomenon to regulate other targeting approaches using either hydrophobic alpha-helix forming peptides [34] or specific targeting peptides. [35] Finally, QDs lacking specific targeting mechanisms such as antibody-antigen or ligandreceptor interactions are able to spatially localize to both subcellular and anatomical structures.…”

Section: Resultsmentioning

confidence: 98%

Mixed-surface, lipid-tethered quantum dots for targeting cells and tissues

Zhang

Haage

Whitley

et al. 2012

Colloids and Surfaces B: Biointerfaces

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Quantum dots (QDs), with their variable luminescent properties, are rapidly transcending traditional labeling techniques in biological imaging and hold vast potential for biosensing applications. An obstacle in any biosensor development is targeted specificity. Here we report a facile procedure for creating QDs targeted to the cell membrane with the goal of cell-surface protease biosensing. This procedure generates water-soluble QDs with variable coverage of lipid functional groups. The resulting hydrophobicity is quantitatively controlled by the molar ratio of lipids per QD. Appropriate tuning of the hydrophobicity ensures solubility in common aqueous cell culture media and while providing affinity to the lipid bilayer of cell membranes. The reaction and exchange process was directly evaluated by measuring UV-vis absorption spectra associated with dithiocarbamate formation. Cell membrane binding was assessed using flow cytometry and total internal reflection fluorescence imaging with live cells, and tissue affinity was measured using histochemical staining and fluorescence imaging of frozen tissue sections. Increases in cell and tissue binding were found to be regulated by both QD hydrophobicity and surface charge, underlying the importance of QD surface properties in the optimization of both luminescence and targeting capability. the hydrophobicity ensures solubility in common aqueous cell culture media and while providing affinity to the lipid bilayer of cell membranes. The reaction and exchange process was directly evaluated by measuring UV-vis absorption spectra associated with dithiocarbamate formation. Cell membrane binding was assessed using flow cytometry and total internal reflection fluorescence imaging with live cells, and tissue affinity was measured using histochemical staining and fluorescence imaging of frozen tissue sections. Increases in cell and tissue binding were found to be regulated by both QD hydrophobicity and surface charge, underlying the importance of QD surface properties in the optimization of both luminescence and targeting capability. Mixed-surface, Lipid-tethered Quantum Dots for Targeting Cells and Tissues

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Mechanism and uses of a membrane peptide that targets tumors and other acidic tissues in vivo

Cited by 271 publications

References 28 publications

Energetics of peptide (pHLIP) binding to and folding across a lipid bilayer membrane

Energetics of peptide (pHLIP) binding to and folding across a lipid bilayer membrane

pH (low) insertion peptide (pHLIP) inserts across a lipid bilayer as a helix and exits by a different path

Mixed-surface, lipid-tethered quantum dots for targeting cells and tissues

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