Chemical Control over T-Cell Activation in Vivo Using Deprotection of trans-Cyclooctene-Modified Epitopes

Tumorimmunolog

Tumor targeting of MMP-2/9 activatable cell-penetrating imaging probes is caused by tumor-independent activation

Activatable cell-penetrating peptides (ACPPs) are a new class of promising molecular imaging probes for the visualization of enzymes in vivo. The cell-penetrating function of a polycationic peptide is efficiently blocked by intramolecular electrostatic interactions with a polyanionic peptide. Proteolysis of a cleavable linker present between the polycationic cell-penetrating peptide and polyanionic peptide affords dissociation of both domains and enables the activated cell-penetrating peptide to enter cells. Here, we aimed to develop an ACPP sensitive to matrix metalloproteinase-2 and -9 (MMP-2/9) for nuclear imaging purposes. Methods: MMP-2/9 ACPPs and nonactivatable cell-penetrating peptides (non-ACPP) were prepared by 9- fluorenylmethyloxycarbonyl solid-phase peptide synthesis and labeled with 177Lu or 177Lu/125I for dual-isotope studies. The in vivo biodistribution of these probes was assessed in MMP-2/9– positive tumor-bearing mice (n 5 6) and healthy mice (n 5 4) using g-counting. Furthermore, a radiolabeled cell-penetrating peptide serving as a positive control was evaluated in tumorbearing mice (n 5 6). Results: Biodistribution studies showed a5-fold-higher retention of ACPP in tumor than in muscle (P , 0.01) and a 6-fold-higher tumor retention relative to non-ACPP (P , 0.01), supporting earlier studies on fluorescently labeled ACPPs proposing activation by tumor-associated MMP-2/9. Surprisingly, however, the uptake of ACPP was significantly higher than that of non-ACPP in almost all tissues (P , 0.01). To unravel the activation process of ACPP in vivo, we developed dual-isotope ACPP analogs (dACPPs) that allowed us to discriminate between uncleaved dACPP and activated dACPP. In vivo biodistribution of dACPP indicated that the tissue-associated counts originated from activated dACPP. Interestingly dACPPadministration to healthy mice, compared with MMP- 2/9–positive tumor-bearing mice, resulted in a similar dACPP biodistribution. Furthermore, a radiolabeled cell-penetrating peptide showed tumor-to-tissue ratios equal to those found for ACPP (P . 0.05). Conclusion: This study demonstrates that the tumor targeting of radiolabeled MMP-2/9 ACPPs is most likely caused by the activation in the vascular compartment rather than tumor-specific activation, as suggested earlier. The results in the present paper indicate that different and more tissue-specific enzyme–ACPP combinations are needed to unleash the full potential of the elegant ACPP concept in living animals

Tumor targeting of MMP-2/9 activatable cell-penetrating imaging probes is caused by tumor-independent activation

Activatable cell-penetrating peptides (ACPPs) are a new class of promising molecular imaging probes for the visualization of enzymes in vivo. The cell-penetrating function of a polycationic peptide is efficiently blocked by intramolecular electrostatic interactions with a polyanionic peptide. Proteolysis of a cleavable linker present between the polycationic cell-penetrating peptide and polyanionic peptide affords dissociation of both domains and enables the activated cell-penetrating peptide to enter cells. Here, we aimed to develop an ACPP sensitive to matrix metalloproteinase-2 and -9 (MMP-2/9) for nuclear imaging purposes. Methods: MMP-2/9 ACPPs and nonactivatable cell-penetrating peptides (non-ACPP) were prepared by 9- fluorenylmethyloxycarbonyl solid-phase peptide synthesis and labeled with 177Lu or 177Lu/125I for dual-isotope studies. The in vivo biodistribution of these probes was assessed in MMP-2/9– positive tumor-bearing mice (n 5 6) and healthy mice (n 5 4) using g-counting. Furthermore, a radiolabeled cell-penetrating peptide serving as a positive control was evaluated in tumorbearing mice (n 5 6). Results: Biodistribution studies showed a5-fold-higher retention of ACPP in tumor than in muscle (P , 0.01) and a 6-fold-higher tumor retention relative to non-ACPP (P , 0.01), supporting earlier studies on fluorescently labeled ACPPs proposing activation by tumor-associated MMP-2/9. Surprisingly, however, the uptake of ACPP was significantly higher than that of non-ACPP in almost all tissues (P , 0.01). To unravel the activation process of ACPP in vivo, we developed dual-isotope ACPP analogs (dACPPs) that allowed us to discriminate between uncleaved dACPP and activated dACPP. In vivo biodistribution of dACPP indicated that the tissue-associated counts originated from activated dACPP. Interestingly dACPPadministration to healthy mice, compared with MMP- 2/9–positive tumor-bearing mice, resulted in a similar dACPP biodistribution. Furthermore, a radiolabeled cell-penetrating peptide showed tumor-to-tissue ratios equal to those found for ACPP (P . 0.05). Conclusion: This study demonstrates that the tumor targeting of radiolabeled MMP-2/9 ACPPs is most likely caused by the activation in the vascular compartment rather than tumor-specific activation, as suggested earlier. The results in the present paper indicate that different and more tissue-specific enzyme–ACPP combinations are needed to unleash the full potential of the elegant ACPP concept in living animals

Douleur de la face postérieure de l'épaule : place de la mésothérapie

Membrane type-1 matrix metalloproteinase (MT1-MMP or MMP-14) plays an important role in adverse cardiac remodelling. Here, we aimed to develop radiolabeled activatable cell penetrating peptides (ACPP) sensitive to MT1-MMP for the detection of elevated MT1-MMP levels in adverse cardiac remodelling. Three ACPP analogs were synthesized and the most potent ACPP analog was selected using MT1-MMP sensitivity and enzyme specificity assays. This ACPP, called ACPP-B, showed high sensitivity towards MT1-MMP, soluble MMP-2, and MT2-MMP, while limited sensitivity was measured for other members of the MMP family. In in vitro cell assays, radiolabeled ACPP-B showed efficient cellular uptake upon activation. A pilot in vivo study showed increased uptake of the radiolabeled probe in regions of infarcted myocardium compared to remote myocardium, warranting further in vivo evaluation

Imaging of MMP activity in postischemic cardiac remodeling using radiolabeled MMP-2/9 activatable peptide probes

The noninvasive imaging of matrix metalloproteinases (MMPs) activity in postischemic myocardial tissue holds great promise to predict cardiac function post-myocardial infarction. Consequently, development of MMP specific molecular imaging probes for noninvasive visualization and quantification of MMP activity is of great interest. A novel MMP imaging strategy is based on activatable cell-penetrating peptide probes (ACPP) that are sensitive to the proteolytic activity of MMP-2 and -9. The MMP-mediated activation of these ACPPs drives probe accumulation at the target site. The aim of this study was the development and characterization of radiolabeled MMP-2/9 sensitive ACPPs to assess MMP activity in myocardial remodeling in vivo. Specifically, a short and long-circulating MMP activatable cell-penetrating imaging probe (ACPP and Alb-ACPP, respectively; the latter is an ACPP modified with an albumin binding ligand that prolongs blood clearance) were successfully synthesized and radiolabeled. Subsequently, their biodistributions were determined in vivo in a Swiss mouse model of myocardial infarction. Both peptide probes showed a significantly higher uptake in infarcted myocardium compared to remote myocardium. The biodistribution for dual-isotope radiolabeled probes, which allowed us to discriminate between uncleaved ACPP and activated ACPP, showed increased retention of activated ACPP and activated Alb-ACPP in infarcted myocardium compared to remote myocardium. The enhanced retention correlated to gelatinase levels determined by gelatin zymography, whereas no correlation was found for the negative control: an MMP-2/9 insensitive non-ACPP. In conclusion, radiolabeled MMP sensitive ACPP probes enable to assess MMP activity in the course of remodeling post-myocardial infarction in vivo. Future research should evaluate the feasibility and the predictive value of the ACPP strategy for assessing MMP activity as a main player in postinfarction myocardial remodeling in vivo. © 2014 American Chemical Society

Overnight urinary cortisol and cortisone add new insights into adaptation to training

Radioimmunotherapy and nuclear imaging (immuno-PET/SPECT) of cancer with radiometal-labeled antibody fragments or peptides is hampered by low tumor-to-kidney ratios because of high renal radiometal retention. Therefore, we developed and evaluated a pretargeting strategy using click chemistry in vivo to reduce kidney uptake and avoid unwanted radiation toxicity. We focused on the bioorthogonal reaction between a trans-cyclooctene (TCO)-functionalized TAG72 targeting diabody, AVP04-07, and a low-molecular-weight radiolabeled tetrazine probe that was previously shown to have low kidney retention and relatively fast renal clearance. METHODS: AVP04-07 diabodies were functionalized with TCO tags, and in vitro immunoreactivity toward bovine submaxillary mucin and tetrazine reactivity were assessed. Next, pretargeting biodistribution studies were performed in LS174T tumor-bearing mice with AVP04-07-TCO(n) (where n indicates the number of TCO groups per diabody) and radiolabeled tetrazine to optimize the TCO modification grade (0, 1.8, or 4.7 TCO groups per diabody) and the (177)Lu-tetrazine dose (0.1, 1.0, or 10 Eq with respect to the diabody). Radiolabeled tetrazine was injected at 47 h after diabody injection, and mice were euthanized 3 h later. A pretargeting SPECT/CT study with (111)In-tetrazine was performed with the optimized conditions. RESULTS: Immunoreactivity for native AVP04-07 was similar to that for TCO-functionalized AVP04-07, and the latter reacted efficiently with radiolabeled tetrazine in vitro. The combination of the pretargeting component AVP04-07 functionalized with 4.7 TCO groups and 1 Eq of (177)Lu-tetrazine with respect to the diabody showed the most promising biodistribution. Specifically, high (177)Lu-tetrazine tumor uptake (6.9 percentage injected dose/g) was observed with low renal retention, yielding a tumor-to-kidney ratio of 5.7. SPECT/CT imaging confirmed the predominant accumulation of radiolabeled tetrazine in the tumor and low nontumor retention. CONCLUSION: Pretargeting provides an alternative radioimmunotherapy and nuclear imaging strategy by overcoming the high renal retention of low-molecular-weight radiometal tumor-homing agents through the separate administration of a tumor-homing agent and a radioactive probe with fast clearance

Evaluation of strained alkynes for Cu-free click reaction in live mice

Introduction: We report on our evaluation of the strain-promoted cyclooctyne-azide cycloaddition reaction for use in tumor pretargeting, comprising a side-by-side comparison of probes 1-3 bearing three distinct cyclooctyne moieties based respectively on the 1st and 2nd generation difluorinated cyclooctyne and the 1st generation dibenzocyclooctyne. Methods: The probes were synthesized and labeled with 177Lu with high yields. The probe stability and reactivity towards azides were evaluated in PBS and mouse serum, and their blood clearance, biodistribution and in vivo reactivity were evaluated in tumor-free mice. Results: In serum the three probes exhibited sufficient stability for a pretargeting application with half-lives of 12-19h. In PBS, probes 2 and 3 were more reactive towards azido-conjugated Rituximab (Rtx-N3) than 1, but in contrast to 1, their reactivity decreased in mouse serum and mouse serum albumin solutions, as a result of covalent and non-covalent interactions with albumin. Biodistribution data confirmed the interactions with serum proteins in circulation: 177Lu-1 showed a fast elimination from blood (t1/2,β = 0.31h), while 177Lu-2 and 177Lu-3 were retained in blood for longer periods of time (t1/2,β = 1.08 and 3.58h, respectively). Dual isotope biodistribution experiments assessing the reaction between 125I-Rtx-N3 and 177Lu-1-3 in circulation in mice showed a very limited retention of 2 and 3 in blood rich organs, indicating a minimal reactivity, while no such retention was observed for 1. Conclusion: The low reactivity of the studied cyclooctynes, and their serum interactions preclude their use at the low in vivo concentrations typical for pretargeting applications

Fluorogenic Bifunctional Trans-cyclooctenes as Efficient Tools for Investigating Click-to-Release Kinetics

The inverse electron demand Diels-Alder pyridazine elimination reaction between tetrazines and allylic substituted trans -cyclooctenes (TCOs) is a key player in bioorthogonal bond cleavage reactions. Determining the rate of elimination on alkylamine substrates has so far proven difficult. Here, we report a fluorogenic tool consisting of a TCO-linked EDANS fluorophore and a DABCYL quencher for accurate detection of both the click and release rates for any tetrazine at physiologically relevant concentrations.Metals in Catalysis, Biomimetics & Inorganic MaterialsBio-organic Synthesi