Sigma receptors (subtypes sigma-1 and sigma-2) are a unique class of binding sites expressed throughout the mammalian body. The endogenous ligand for these sites has not been identified, but steroid hormones (particularly progesterone), sphingolipid-derived amines and N,N-dimethyltryptamine can bind with fairly high affinity. Sigma receptors are overexpressed in rapidly proliferating cells, like cancer cells. Particularly the sigma-2 subtype is upregulate when cells divide and down regulated when they become quiescent. Sigma ligands, especially sigma-2 agonists, can inhibit proliferation and induce apoptosis by a mechanism involving changes in cytosolic Ca(2+), ceramide and sphingolipid levels. Tumor cells are much more sensitive to such treatment than cells from their tissue of origin. Sigma ligands induce apoptosis not only in drug-sensitive but also in drug-resistant cancer cells (e.g., cells with p53 mutations, or caspase dysfunction). Moreover, sigma ligands may abrogate P-glycoprotein-mediated drug resistance and at subtoxic doses, they can potentiate the effect of conventional cytostatics. Thus, sigma-2 agonists may be developed as antineoplastic agents for the treatment of drug-resistant tumors. A large number of radiolabeled sigma ligands has been prepared for SPECT (single-photon emission computed tomography) and PET (positron emission tomography) imaging. Such radiopharmaceuticals can be used for tumor detection, tumor staging, and evaluation of anti-tumor therapy. There is still a need for the development of ligands with (1) high selectivity for the sigma-2 subtype, (2) defined action (agonist or antagonist) and (3) optimal pharmacokinetics (low affinity for P-glycoprotein, high and specific tumor uptake, and rapid washout from non-target tissues).
Permeability of the blood-brain barrier (BBB) is one of the factors determining the bioavailability of therapeutic drugs. The BBB only allows entry of lipophilic compounds with low molecular weights by passive diffusion. However, many lipophilic drugs show negligible brain uptake. They are substrates for transporters such as P-glycoprotein (P-gp), multidrug-resistance associated protein (MRP) and organic anion transporting polypeptides (OATPs). The action of these carrier systems results in rapid efflux of xenobiotics from the central nervous system (CNS). Classification of candidate drugs as substrates or inhibitors of such carrier proteins is of crucial importance in drug development. Positron emission tomography (PET) can play an important role in the screening process by providing in vivo information, after the putative drug has passed in vitro tests. Although radiolabeled probes for MRP and OATP function are not yet available, many radiotracers have been prepared to study P-glycoprotein function in vivo with PET. These include alkaloids ((11)C-colchicine), antineoplastic agents ((11)C-daunorubicin, (18)F-paclitaxel), modulators of L-type calcium channels ((11)C-(+/-)verapamil, (11)C-R(+)-verapamil), beta-adrenoceptor antagonists ((11)C-(S)-carazolol, (18)F-(S)-1'-fluorocarazolol, (11)C-carvedilol), serotonin 5-HT(1A) receptor antagonists ((18)F-MPPF), opioid receptor antagonists ((11)C-loperamide, (11)C-carfentanyl), and various (64)Cu-labeled copper complexes. Studies in experimental animals have indicated that it is possible to assess P-glycoprotein function in the BBB and its effect on the uptake and binding of drugs within the intact CNS, using suitable P-gp modulators labeled with positron emitters. Provided that radiopharmaceuticals (and P-gp modulators) can be developed for human use, several exciting fields of study may be explored, viz. (i) direct evaluation of the effect of modulators on the cerebral uptake of therapeutic drugs; (ii) assessment of mechanisms underlying drug resistance in epilepsy; (iii) examination of the role of the BBB in the pathophysiology of neurodegenerative and affective disorders; and (iv) exploration of the relationship between polymorphisms of transporter genes and the pharmacokinetics of test compounds within the CNS.
Sigma receptors (sigma-1 and sigma-2) represent two independent classes of proteins. Their endogenous ligands may include the hallucinogen N,N-dimethyltryptamine (DMT) and sphingolipid-derived amines which interact with sigma-1 receptors, besides steroid hormones (e.g., progesterone) which bind to both sigma receptor subpopulations. The sigma-1 receptor is a ligand-regulated molecular chaperone with various ion channels and G-protein-coupled membrane receptors as clients. The sigma-2 receptor was identified as the progesterone receptor membrane component 1 (PGRMC1). Although sigma receptors are over-expressed in tumors and up-regulated in rapidly dividing normal tissue, their ligands induce significant cell death only in tumor tissue. Sigma ligands may therefore be used to selectively eradicate tumors. Multiple mechanisms appear to underlie cell killing after administration of sigma ligands, and the signaling pathways are dependent both on the type of ligand and the type of tumor cell. Recent evidence suggests that the sigma-2 receptor is a potential tumor and serum biomarker for human lung cancer and an important target for inhibiting tumor invasion and cancer progression. Current radiochemical efforts are focused on the development of subtype-selective radioligands for positron emission tomography (PET) imaging. Right now, the mostpromising tracers are [18F]fluspidine and [18F]FTC-146 for sigma-1 receptors and [11C]RHM-1 and [18F]ISO-1 for the sigma-2 subtype. Nanoparticles coupled to sigma ligands have shown considerable potential for targeted delivery of antitumor drugs in animal models of cancer, but clinical studies exploring this strategy in cancer patients have not yet been reported. This article is part of a Special Issue entitled: Membrane channels and transporters in cancers.
(11)C-7 is a novel tracer of P-gp function with higher baseline uptake than (11)C-verapamil. Upregulation of P-gp function in response to treatment (which is hard to detect with (11)C-verapamil) may be detectable using (11)C-7 and PET. Because (11)C-6 shows specific binding in target organs, this compound is the first PET tracer allowing measurement of P-gp expression.
RationaleDopamine stabilizers have stimulatory actions under low dopamine tone and inhibitory actions under high dopamine tone without eliciting catalepsy. These compounds are dopamine D2 receptor (D2R) antagonists or weak partial agonists and may have pro-mnemonic and neuroprotective effects. The mechanism underlying their stimulatory and neuroprotective actions is unknown but could involve sigma-1R binding.ObjectivesThe present study examined sigma-1R and D2R occupancy by the dopamine stabilizer pridopidine (ACR16) at behaviorally relevant doses in living rats.MethodsRats were administered 3 or 15 mg/kg pridopidine, or saline, before injection of the radiotracer 11C-SA4503 (sigma-1R) or 11C-raclopride (D2R). Some animals received 60 mg/kg pridopidine and were only scanned with 11C-raclopride. Cerebral 11C-SA4503 binding was quantified using metabolite-corrected plasma input data and distribution volume (VT) calculated by Logan graphical analysis. 11C-raclopride binding was quantified using striatum-to-cerebellum ratios and binding potentials calculated with a simplified reference tissue model.ResultsCunningham-Lassen plots indicated sigma-1R occupancies of 57 ± 2 and 85 ± 2 % after pretreatment of animals with 3 and 15 mg/kg pridopidine. A significant (44–66 %) reduction of 11C-raclopride binding was only observed at 60 mg/kg pridopidine.ConclusionsAt doses shown to elicit neurochemical and behavioral effects, pridopidine occupied a large fraction of sigma-1Rs and a negligible fraction of D2Rs. Significant D2R occupancy was only observed at a dose 20-fold higher than was required for sigma-1R occupancy. The characteristics of dopamine stabilizers may result from the combination of high sigma-1R and low D2R affinity.
BackgroundAdvanced melanoma is characterized by a pronounced resistance to therapy leading to a limited patient survival of ~6 - 9 months. Here, we report on a novel bifunctional therapeutic fusion protein, designated anti-MCSP:TRAIL, that is comprised of a melanoma-associated chondroitin sulfate proteoglycan (MCSP)-specific antibody fragment (scFv) fused to soluble human TRAIL. MCSP is a well-established target for melanoma immunotherapy and has recently been shown to provide important tumorigenic signals to melanoma cells. TRAIL is a highly promising tumoricidal cytokine with no or minimal toxicity towards normal cells. Anti-MCSP:TRAIL was designed to 1. selectively accrete at the cell surface of MCSP-positive melanoma cells and inhibit MCSP tumorigenic signaling and 2. activate apoptotic TRAIL-signaling.ResultsTreatment of a panel of MCSP-positive melanoma cell lines with anti-MCSP:TRAIL induced TRAIL-mediated apoptotic cell death within 16 h. Of note, treatment with anti-MCSP:sTRAIL was also characterized by a rapid dephosphorylation of key proteins, such as FAK, implicated in MCSP-mediated malignant behavior. Importantly, anti-MCSP:TRAIL treatment already inhibited anchorage-independent growth by 50% at low picomolar concentrations, whereas > 100 fold higher concentrations of non-targeted TRAIL failed to reduce colony formation. Daily i.v. treatment with a low dose of anti-MCSP:TRAIL (0.14 mg/kg) resulted in a significant growth retardation of established A375 M xenografts. Anti-MCSP:TRAIL activity was further synergized by co-treatment with rimcazole, a σ-ligand currently in clinical trials for the treatment of various cancers.ConclusionsAnti-MCSP:TRAIL has promising pre-clinical anti-melanoma activity that appears to result from combined inhibition of tumorigenic MCSP-signaling and concordant activation of TRAIL-apoptotic signaling. Anti-MCSP:TRAIL alone, or in combination with rimcazole, may be of potential value for the treatment of malignant melanoma.
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