PET Imaging of Extracellular pH in Tumors with<sup>64</sup>Cu- and<sup>18</sup>F-Labeled pHLIP Peptides: A Structure–Activity Optimization Study

Demoin, Dustin Wayne; Wyatt, Linden C.; Edwards, Kimberly J.; Abdel-Atti, Dalya; Sarparanta, Mirkka; Pourat, Jacob; Longo, Valerie A.; Carlin, Sean D.; Engelman, Donald M.; Andreev, Oleg A.; Reshetnyak, Yana K.; Viola-Villegas, Nerissa; Lewis, Jason S.

doi:10.1021/acs.bioconjchem.6b00306

Cited by 55 publications

(90 citation statements)

References 21 publications

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“…The pHLIP peptides find a wide range of applications in biomedical sciences 16,20–22,43,44 and, also, they prove to be a very convenient model system for the investigation of polypeptide insertion into the lipid bilayer of a membrane triggered by pH. 12,28 Whereas various spectroscopic methods applied previously probed changes in the conformation of peptides, SAXS employed in this study allowed us, for the first time, to monitor the changes in the liposome and lipid bilayer structure.…”

Section: Discussionmentioning

confidence: 99%

pHLIP Peptide Interaction with a Membrane Monitored by SAXS

et al. 2016

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pH (Low) Insertion Peptides (pHLIP peptides) find application in studies of membrane-associated folding because spontaneous insertion of these peptides is conveniently triggered by varying pH. Here, we employed small-angle X-ray scattering (SAXS) to investigate a wild-type (WT) pHLIP peptide oligomeric state in solution at high concentrations and monitor changes in the liposome structure upon peptide insertion into the bilayer. We established that even at high concentrations (up to 300 µM) the WT pHLIP peptide at pH 8.0 does not form oligomers larger than tetramers (which exhibit concentration-dependent transfer to the monomeric state, as was shown previously). This finding has significance for medical applications when high concentration of the peptide is injected into blood and diluted in blood circulation. The interaction of WT pHLIP peptide with liposomes does not alter the unilamellar vesicle structure upon peptide adsorption by the lipid bilayer at high pH or upon insertion across the bilayer at low pH. At the same time, SAXS data clearly demonstrate the insertion of the peptide into the membrane at low pH, which opens the possibility of investigating the kinetic process of polypeptide insertion and exit from the membrane in real time by time-resolved SAXS.

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Section: Discussionmentioning

confidence: 99%

pHLIP Peptide Interaction with a Membrane Monitored by SAXS

et al. 2016

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“…Variation of the WT pHLIP sequence led to novel pHLIPs, such as Variant 3 (Var3), with significantly improved tumor targeting properties [18, 28, 33–35]. The overall features of the pHLIP peptide sequences are still present in all variants: a middle region interspersed with a combination of hydrophobic residues and residues that are negatively charged at physiological pH but become neutrally charged at low pH, and hydrophilic flanking regions, with the membrane-inserting C-terminus (in most sequences) containing a few additional protonatable residues (Box 1) [9, 36–38].…”

Section: Phlip Technologymentioning

confidence: 99%

“…One of the main challenges in PET/SPECT imaging is to obtain images of target tissue that contrast highly with the image background, motivating the use of a targeting agent. When a radionuclide is conjugated to the non-inserting terminus of a pHLIP (Figure 3A), the resulting construct not only targets tumor tissue very well, but also remains securely in the tumor long enough to allow the excess, non-inserted construct to clear from normal tissues, resulting in higher contrast images [17, 23, 25, 29, 33]. Success has been seen using the radioisotopes 18 F (9 ± 2 %ID/g at 4 h p.i.)…”

Section: Applications Of Phlip Technologymentioning

confidence: 99%

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Applications of pHLIP Technology for Cancer Imaging and Therapy

Wyatt

Lewis

Andreev

et al. 2017

Trends in Biotechnology

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Acidity is a biomarker of cancer that is not subject to the blunting clonal selection effects that reduce the efficacy of other biomarker technologies, like antibody targeting. The pH (Low) Insertion Peptides (pHLIPs) provide new opportunities for targeting acidic tissues. Through the physical mechanism of membrane-associated folding, pHLIPs are triggered by the acidic microenvironment to insert and span the membranes of tumor cells. The pHLIP platform can be applied to imaging acidic tissues, delivering cell-permeable and impermeable molecules to the cytoplasm, and promoting the cellular uptake of nanoparticles. Since acidosis is a hallmark of tumor development, progression, and aggressiveness, the pHLIP technology may prove useful in targeting cancer cells and metastases for tumor diagnosis, imaging, and therapy.

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“…CT reinforces the clinical utility of PET in several ways that enhance diagnostic accuracy: the spatio-anatomic reference given by CT assists in the generation of quantitative PET data by providing a tissue-density map to facilitate appropriate correction for attenuation effects 47 ; it assists clinicians in recognition of false-positive tracer uptake 48 ; and it assists in identifying precise tumour margins for optimal subsequent care 49 (for example, biopsy, resection or monitoring). The availability of both fluorinated small molecules, and more recently macromolecules labelled with a variety of radiometals, has promoted further applications in PET-CT (Table 4; SI Table 1 50,51 ).…”

Section: Pet-ctmentioning

confidence: 99%

Multiplexed imaging for diagnosis and therapy

et al. 2017

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Complex molecular and metabolic phenotypes depict cancers as a constellation of different diseases with common themes. Precision imaging of such phenotypes requires flexible and tuneable modalities capable of identifying phenotypic fingerprints by using a restricted number of parameters whilst ensuring sensitivity to dynamic biological regulation. Common phenotypes can be detected by in vivo imaging technologies, and effectively define the emerging standards for disease classification and patient stratification in radiology. However, for the imaging data to accurately represent a complex fingerprint, the individual imaging parameters need to be measured and analysed in relation to their wider spatial and molecular context. In this respect, targeted palettes of molecular imaging probes facilitate the detection of heterogeneity in oncogene-driven alterations and their response to treatment, and lead to the expansion of rational-design elements for the combination of imaging experiments. In this Review, we evaluate criteria for conducting multiplexed imaging, and discuss its opportunities for improving patient diagnosis and the monitoring of therapy.

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PET Imaging of Extracellular pH in Tumors with⁶⁴Cu- and¹⁸F-Labeled pHLIP Peptides: A Structure–Activity Optimization Study

Cited by 55 publications

References 21 publications

pHLIP Peptide Interaction with a Membrane Monitored by SAXS

pHLIP Peptide Interaction with a Membrane Monitored by SAXS

Applications of pHLIP Technology for Cancer Imaging and Therapy

Multiplexed imaging for diagnosis and therapy

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PET Imaging of Extracellular pH in Tumors with64Cu- and18F-Labeled pHLIP Peptides: A Structure–Activity Optimization Study

Cited by 55 publications

References 21 publications

pHLIP Peptide Interaction with a Membrane Monitored by SAXS

pHLIP Peptide Interaction with a Membrane Monitored by SAXS

Applications of pHLIP Technology for Cancer Imaging and Therapy

Multiplexed imaging for diagnosis and therapy

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Product

Resources

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PET Imaging of Extracellular pH in Tumors with⁶⁴Cu- and¹⁸F-Labeled pHLIP Peptides: A Structure–Activity Optimization Study