Combination of high-fat/high-fructose diet and low-dose streptozotocin to model long-term type-2 diabetes complications.

The epidemic of type 2 diabetes mellitus (T2DM) is fueled by added fructose consumption. Here, we thus combined high-fat/high-fructose diet, with multiple low-dose injections of streptozotocin (HF/HF/Stz) to emulate the long-term complications of T2DM. HF/HF/Stz rats, monitored over 56 weeks, exhibited metabolic dysfunctions associated with the different stages of the T2DM disease progression in humans: an early prediabetic phase characterized by an hyperinsulinemic period with modest dysglycemia, followed by a late stage of T2DM with frank hyperglycemia, normalization of insulinemia, marked dyslipidemia, hepatic fibrosis and pancreatic ß-cell failure. Histopathological analyses combined to [18F]-FDG PET imaging further demonstrated the presence of several end-organ long-term complications, including reduction in myocardial glucose utilization, renal dysfunction as well as microvascular neuropathy and retinopathy. We also provide for the first time a comprehensive µ-PET whole brain imaging of the changes in glucose metabolic activity within discrete cerebral regions in HF/HF/Stz diabetic rats. Altogether, we developed and characterized a unique non-genetic preclinical model of T2DM adapted to the current diet and lifestyle that recapitulates the major metabolic features of the disease progression, from insulin resistance to pancreatic ß-cell dysfunction, and closely mimicking the target-organ damage occurring in type 2 diabetic patients at advanced stages.

Regional and subcellular distribution of the receptor-targeting protein PIST in the rat central nervous system.

Protein interacting specifically with Tc10, PIST, is a Golgi-associated sorting protein involved in regulating cell-surface targeting of plasma membrane receptors. The present study provides the first comprehensive description of PIST distribution in the mammalian central nervous system and of its subcellular localization by immunocytochemistry. PIST is distributed widely throughout the neuraxis, predominantly associated with neuronal cell bodies and dendrites. In hippocampal neurons, in vitro and in situ, PIST displayed a patchy subcellular distribution in an area surrounding the nucleus and extending into one of the major dendrites. By colocalization with the trans-Golgi marker TGN38, we were able to show that PIST is associated largely but not exclusively with the trans-Golgi network in central neurons. High or moderate to high levels of PIST-like immunoreactivity were found in cortical areas, in particular in layer V of the neocortex. The motor cortex was most strongly labeled. Also, the piriform and insular cortices displayed strong PIST labeling. In the hippocampus, CA2 but not CA1 or CA3 pyramidal cells displayed strong PIST-labeling, extending into their apical dendrites. In the thalamus, ventrolateral and laterodorsal nuclei were most strongly stained, whereas in the hypothalamus the supraoptic nucleus stood out with strong immunoreactivity. Strikingly, in the brainstem all cranial nerve motor nuclei were PIST-positive at varying levels, which is in keeping with the prominent expression of PIST in forebrain motor areas. This selective distribution of PIST suggests that the protein serves distinctive roles in specific neuronal populations, establishing functionally distinct zones, for instance, in the hippocampus.

Evidence for a role of NTS2 receptors in the modulation of tonic pain sensitivity.

BACKGROUND: Central neurotensin (NT) administration results in a naloxone-insensitive antinociceptive response in animal models of acute and persistent pain. Both NTS1 and NTS2 receptors were shown to be required for different aspects of NT-induced analgesia. We recently demonstrated that NTS2 receptors were extensively associated with ascending nociceptive pathways, both at the level of the dorsal root ganglia and of the spinal dorsal horn. Then, we found that spinally administered NTS2-selective agonists induced dose-dependent antinociceptive responses in the acute tail-flick test. In the present study, we therefore investigated whether activation of spinal NTS2 receptors suppressed the persistent inflammatory pain symptoms observed after intraplantar injection of formalin. RESULTS: We first demonstrated that spinally administered NT and NT69L agonists, which bind to both NTS1 and NTS2 receptors, significantly reduced pain-evoked responses during the inflammatory phase of the formalin test. Accordingly, pretreatment with the NTS2-selective analogs JMV-431 and levocabastine was effective in inhibiting the aversive behaviors induced by formalin. With resolution at the single-cell level, we also found that activation of spinal NTS2 receptors reduced formalin-induced c-fos expression in dorsal horn neurons. However, our results also suggest that NTS2-selective agonists and NTS1/NTS2 mixed compounds differently modulated the early (21-39 min) and late (40-60 min) tonic phase 2 and recruited endogenous pain inhibitory mechanisms integrated at different levels of the central nervous system. Indeed, while non-selective drugs suppressed pain-related behaviors activity in both part of phase 2, intrathecal injection of NTS2-selective agonists was only efficient in reducing pain during the late phase 2. Furthermore, assessment of the stereotypic pain behaviors of lifting, shaking, licking and biting to formalin also revealed that unlike non-discriminative NTS1/NTS2 analogs reversing all nociceptive endpoint behaviors, pure NTS2 agonists specifically inhibited paw lifting, supporting a role of NTS2 in spinal modulation of persistent nociception. CONCLUSION: The present study provides the first demonstration that activation of NTS2 receptors produces analgesia in the persistent inflammatory pain model of formalin. The dichotomy between these two classes of compounds also indicates that both NTS1 and NTS2 receptors are involved in tonic pain inhibition and implies that these two NT receptors modulate the pain-induced behavioral responses by acting on distinct spinal and/or supraspinal neural circuits. In conclusion, development of NT agonists targeting both NTS1 and NTS2 receptors could be useful for chronic pain management.

Central delivery of Dicer-substrate siRNA: a direct application for pain research.

RNA interference (RNAi) is gaining acceptance as a potential therapeutic strategy against peripheral disease, and several clinical trials are already underway with 21-mer small-interfering RNA (siRNA) as the active pharmaceutical agent. However, for central affliction like pain, such innovating therapies are limited but nevertheless crucial to improve pain research and management. We demonstrate here the proof-of-concept of the use of 27-mer Dicer-substrate siRNA (DsiRNA) for silencing targets related to CNS disorders such as pain states. Indeed, low dose DsiRNA (0.005 mg/kg) was highly efficient in reducing the expression of the neurotensin receptor-2 (NTS2, a G-protein-coupled receptor (GPCR) involved in ascending nociception) in rat spinal cord through intrathecal (IT) administration formulated with the cationic lipid i-Fect. Along with specific decrease in NTS2 mRNA and protein, our results show a significant alteration in the analgesic effect of a selective-NTS2 agonist, reaching 93% inhibition up to 3-4 days after administration of DsiRNA. In order to ensure that these findings were not biased by unsuspected off-target effects (OTEs), we also demonstrated that treatment with a second NTS2-specific DsiRNA also reversed NTS2-induced antinociception, and that NTS2-specific 27-mer duplexes did not alter signaling through NTS1, a closely related receptor. Altogether, DsiRNAi represents a potent tool for dissecting nociceptive pathways and could further lead to a new class of central active drugs.

Spinal NTS1 receptors regulate nociceptive signaling in a rat formalin tonic pain model.

Central administration of the neuropeptide neurotensin (NT) was shown to induce antinociceptive responses both spinally and supraspinally. Although NTS2 receptors play an important role in modulating the activity of spinal neurons, we have recently implicated NTS1 receptors in NT's analgesic effects in acute spinal pain paradigms. The current experiments were thus designed to examine the antinociceptive effects of intrathecal administration of NTS1 agonists in formalin-induced tonic pain in rats. We first established, using immunoblotting and immunohistochemical approaches, that NTS1 receptors were present in small- and medium-sized dorsal root ganglion cells and localized in the superficial layers of the dorsal horn of the spinal cord. We then examined the effects of intrathecal injection of NT (1-15 microg/kg) or NTS1 preferring agonists on the nocifensive response to intraplantar formalin. Both NTS1-agonists, PD149163 (10-120 microg/kg) and NT69L (1-100 microg/kg), dose-dependently attenuated the formalin-induced behaviors. Accordingly, NTS1 agonists markedly suppressed pain-evoked c-fos expression in the superficial, nucleus proprius and neck regions of the spinal dorsal horn. The concomitant administration of PD149163 with the NTS1 antagonist SR48692 (3 microg/kg) significantly reversed PD149163-induced antinociception, confirming the implication of NTS1 in tonic pain. In contrast, NT69L's analgesic effects were partly abolished by co-administration of SR48692, indicating that NT69L-induced effects may also be exerted through interaction with NTS2. These results demonstrate that NTS1 receptors play a key role in the mediation of the analgesic effects of NT in persistent pain and suggest that NTS1-selective agonists may represent a new line of analgesic compounds.