Neurosteroids Allopregnanolone Sulfate and Pregnanolone Sulfate Have Diverse Effect on the α Subunit of the Neuronal Voltage-gated Sodium Channels Nav1.2, Nav1.6, Nav1.7, and Nav1.8 Expressed in Xenopus Oocytes

Pregnenolone sulfate potentiates tetrodotoxin-resistant Na+ channels to increase the excitability of dural afferent neurons in rats

BACKGROUND

Although peripheral administration of pregnenolone sulfate (PS) has been reported to produce pronociceptive effects, the mechanisms by which PS modulates the excitability of nociceptive neurons are poorly understood. Here, we report on the excitatory role of PS in peripheral nociceptive neurons, focusing on its effects on tetrodotoxin-resistant (TTX-R) Na+ channels.

METHODS

TTX-R Na+ current (INa) mediated by NaV1.8 was recorded from acutely isolated small-sized dural afferent neurons of rats, identified with the retrograde fluorescent dye DiI, using a whole-cell patch-clamp technique.

RESULTS

Transcripts for enzymes and transporters involved in PS biosynthesis were detected in the ophthalmic branch of the trigeminal ganglia. In voltage-clamp mode, PS preferentially potentiated the TTX-R persistent INa, a small non-inactivating current during sustained depolarization. PS shifted the voltage-inactivation relationship toward a depolarizing range. PS also delayed the onset of inactivation and accelerated the recovery from inactivation of TTX-R Na+ channels. Additionally, PS decreased the extent of use-dependent inhibition of TTX-R Na+ channels. In current-clamp mode, PS hyperpolarized dural afferent neurons by increasing the leak K+ conductance. Nevertheless, PS decreased the rheobase current-the minimum current required to generate action potentials-and increased the number of action potentials elicited by depolarizing current stimuli.

CONCLUSION

We have shown that the excitatory neurosteroid PS preferentially potentiates TTX-R persistent INa and reduces the inactivation of TTX-R Na+ channels, resulting in increased excitability of dural afferent neurons. The potential role of endogenous PS in migraine pathology warrants further investigation.

Glucocorticoid Receptor Contributes to Electroacupuncture-Induced Analgesia by Inhibiting Nav1.7 Expression in Rats With Inflammatory Pain Induced by Complete Freund's Adjuvant

BACKGROUND

While electroacupuncture (EA) has been used traditionally for the treatment of chronic pain, its analgesic mechanisms have not been fully clarified. We observed in an earlier study that EA could reverse inflammatory pain and suppress high Nav1.7 expression. However, the molecular mechanism underlying Nav1.7 expression regulation is unclear. In this study, we studied the relationship between the glucocorticoid receptor (GR) and Nav1.7 and the role of these molecules in EA analgesia.

MATERIALS AND METHODS

In this study, we established an inflammatory pain model by intraplantar injection of complete Freund's adjuvant (CFA) in rats. EA stimulation was applied to the ipsilateral "Huantiao" (GB30) and "Zusanli" (ST36) acupoints in the rat model. Western blotting, real-time polymerase chain reaction, immunostaining, intrathecal injection, and chromatin immunoprecipitation (ChIP) assay were performed to determine whether the sodium channel protein Nav1.7 plays a role in CFA-induced pain and whether GR regulates Nav1.7 expression during analgesia following EA stimulation.

RESULTS

EA application significantly decreased the paw withdrawal threshold thresholds and thermal paw withdrawal latency and suppressed GR and Nav1.7 expression in the dorsal root ganglion. Moreover, treatment with a GR sense oligonucleotide (OND) markedly reversed these alterations. In contrast, treatment with a GR antisense OND along with EA application exerted a better analgesic effect, which was accompanied by the suppression of Nav1.7 and GR protein expression. The ChIP assay showed that the binding activity of GR to the Nav1.7 promoter was enhanced in CFA injected rats and suppressed in EA-treated rats.

CONCLUSIONS

The present study demonstrated that EA exerted anti-hyperalgesic effects by inhibiting GR expression, which led to Nav1.7 expression modulation in the rat model of CFA-induced inflammatory pain.

Steroid disulfates - Sulfation double trouble

Sulfation pathways have recently come into the focus of biomedical research. For steroid hormones and related compounds, sulfation represents an additional layer of regulation as sulfated steroids are more water-soluble and tend to be biologically less active. For steroid diols, an additional sulfation is possible, carried out by the same sulfotransferases that catalyze the first sulfation step. The steroid disulfates that are formed are the focus of this review. We discuss both their biochemical production as well as their putative biological function. Steroid disulfates have also been linked to various clinical conditions in numerous untargeted metabolomics studies. New analytical techniques exploring the biosynthetic routes of steroid disulfates have led to novel insights, changing our understanding of sulfation in human biology. They promise a bright future for research into sulfation pathways, hopefully too for the diagnosis and treatment of several associated diseases.

Rapid effects of neurosteroids on neuronal plasticity and their physiological and pathological implications

Current neuroscience research on neurosteroids and their synthetic analogues - neuroactive steroids - clearly demonstrate their drug likeness in a variety of neurological and psychiatric conditions. Moreover, research on neurosteroids continues to provide novel mechanistic insights into receptor activation or inhibition of various receptors. This mini-review will provide a high-level overview of the research area and discuss the various classes of potential physiological and pathological implications discovered so far.

Identification of WB4101, an α1-Adrenoceptor Antagonist, as a Sodium Channel Blocker

Sodium channels are important proteins in modulating neuronal membrane excitability. Genetic studies from patients and animals have indicated neuronal sodium channels play key roles in pain sensitization. We identified WB4101 (2-(2,6-Dimethoxyphenoxyethyl)aminomethyl-1,4-benzodioxane hydrochloride), an antagonist of α1-adrenoceptor, as a Nav1.7 inhibitor from a screen. The present study characterized the effects of WB4101 on sodium channels. We demonstrated that WB4101 inhibited both Nav1.7 and Nav1.8 channels with similar levels of potency. The half-inhibition concentrations (IC50 values) of WB4101 were 11.6 ± 2.07 and 1.0 ± 0.07 µM for the resting and inactivated Nav1.7 channels, respectively, and 8.67 ± 1.31 and 0.91 ± 0.25 µM for the resting and inactivated Nav1.8 channels, respectively. WB4101 induced a hyperpolarizing shift in the voltage-dependent inactivation for both Nav1.7 (15 mV) and Nav1.8 (20 mV) channels. The IC50 values for the open-state sodium channel were 2.50 ± 1.16 µM for Nav1.7 and 1.1 ± 0.2 µM for Nav1.8, as determined by the block of persistent late currents in inactivation-deficient Nav1.7 and Nav1.8 channels, respectively. Consistent with the state-dependent block, the drug also displayed use-dependent inhibitory properties on both wild-type Nav1.7 and Nav1.8 channels, which were removed by the local anesthetic-insensitive mutations but still existed in the inactivation-deficient channels. Further, the state-dependent inhibition on sodium channels induced by WB4101 was demonstrated in dorsal root ganglion neurons. In conclusion, the present study identified WB4101 as a sodium channel blocker with an open-state-dependent property, which may contribute to WB4101's analgesic action.

Antidepressants inhibit Nav1.3, Nav1.7, and Nav1.8 neuronal voltage-gated sodium channels more potently than Nav1.2 and Nav1.6 channels expressed in Xenopus oocytes

Tricyclic antidepressants (TCAs) and duloxetine are used to treat neuropathic pain. However, the mechanisms underlying their analgesic effects remain unclear. Although many investigators have shown inhibitory effects of antidepressants on voltage-gated sodium channels (Na_v) as a possible mechanism of analgesia, to our knowledge, no one has compared effects on the diverse variety of sodium channel α subunits. We investigated the effects of antidepressants on sodium currents in Xenopus oocytes expressing Na_v1.2, Na_v1.3, Na_v1.6, Na_v1.7, and Na_v1.8 with a β₁ subunit by using whole-cell, two-electrode, voltage clamp techniques. We also studied the role of the β₃ subunit on the effect of antidepressants on Na_v1.3. All antidepressants inhibited sodium currents in an inactivated state induced by all five α subunits with β₁. The inhibitory effects were more potent for Na_v1.3, Na_v1.7, and Na_v1.8, which are distributed in dorsal root ganglia, than Na_v1.2 and Na_v1.6, which are distributed primarily in the central nervous system. The effect of amitriptyline on Na_v1.7 with β₁ was most potent with a half-maximal inhibitory concentration (IC₅₀) 4.6 μmol/L. IC₅₀ for amitriptyline on Na_v1.3 coexpressed with β₁ was lowered from 8.4 to 4.5 μmol/L by coexpression with β₃. Antidepressants predominantly inhibited the sodium channels expressed in dorsal root ganglia, and amitriptyline has the most potent inhibitory effect. This is the first evidence, to our knowledge, showing the diverse effects of antidepressants on various α subunits. Moreover, the β₃ subunit appears important for inhibition of Na_v1.3. These findings may aid better understanding of the mechanisms underlying the pain relieving effects of antidepressants.

Loperamide inhibits sodium channels to alleviate inflammatory hyperalgesia

Previous studies demonstrated that Loperamide, originally known as an anti-diarrheal drug, is a promising analgesic agent primarily targeting mu-opioid receptors. However some evidences suggested that non-opioid mechanisms may be contributing to its analgesic effect. In the present study, Loperamide was identified as a Nav1.7 blocker in a pilot screen. In HEK293 cells expressing Nav1.7 sodium channels, Loperamide blocked the resting state of Nav1.7 channels (IC₅₀ = 1.86 ± 0.11 μM) dose-dependently and reversibly. Loperamide produced a 10.4 mV of hyperpolarizing shift for the steady-state inactivation of Nav1.7 channels without apparent effect on the voltage-dependent activation. The drug displayed a mild use- and state-dependent inhibition on Nav1.7 channels, which was removed by the local anesthetic-insensitive construct Nav1.7-F1737A. Inhibition of Nav1.7 at resting state was not altered significantly by the F1737A mutation. Compared to its effects on Nav1.7, Loperamide exhibited higher potency on recombinant Nav1.8 channels in ND7/23 cells (IC₅₀ = 0.60 ± 0.10 μM) and weaker potency on Nav1.9 channels (3.48 ± 0.33 μM). Notably more pronounced inhibition was observed in the native Nav1.8 channels (0.11 ± 0.08 μM) in DRG neurons. Once mu-opioid receptor was antagonized by Naloxone in DRG neurons, potency of Loperamide on Nav1.8 was identical to that of recombinant Nav1.8 channels. The inhibition on Nav channels may be the main mechanism of Loperamide for pain relief beyond mu-opioid receptor. In the meanwhile, the opioid receptor pathway may also influence the blocking effect of Loperamide on sodium channels, implying a cross-talk between sodium channels and opioid receptors in pain processing.

Preliminary evidence of altered steroidogenesis in women with Alzheimer's disease: Have the patients "OLDER" adrenal zona reticularis?

Alzheimer's disease (AD) represents more than half of total dementias. Various factors including altered steroid biosynthesis may participate in its pathophysiology. We investigated how the circulating steroids (measured by GC-MS and RIA) may be altered in the presence of AD. Sixteen women with AD and 22 age- and BMI-corresponding controls aged over 65 years were enrolled in the study. The steroid levels (47 steroids and steroid polar conjugates) and their ratios in AD female patients indicated increased CYP11A1 activity, weakened activity of the CYP17A1C17,20 lyase metabolic step and attenuated sulfotransferase SULT2A1 activity at higher activity of the CYP17A1 17-hydroxylase step. The patients showed diminished HSD3B2 activity for C21 steroids, abated conversion of 17-hydroxyprogesterone to cortisol, and significantly elevated cortisol. The women with AD had also attenuated steroid 7α-hydroxylation forming immunoprotective Δ(5)-C19 steroids, attenuated aromatase activity forming estradiol that induces autoimmunity and a shift from the 3β-hydroxy-5α/β-reduced C19 steroids to their neuroinhibitory and antiinflammatory GABAergic 3α-hydroxy- counterparts and showed higher levels of the 3α-hydroxy-5α/β-reduced C21 steroids and pregnenolone sulfate (improves cognitive abilities but may be both protective and excitotoxic). Our preliminary data indicated functioning of alternative "backdoor" pathway in women with AD showing higher levels of both 5α/β-reduced C21 steroids but reduced levels of both 5α/β-reduced C21 steroids, which implied that the alternative "backdoor" pathway might include both 5α- and 5β-reduced steroids. Our study suggested relationships between AD status in women based on the age of subjects and levels of 10 steroids measured by GC-MS.

Structure and function of μ-conotoxins, peptide-based sodium channel blockers with analgesic activity

μ-Conotoxins block voltage-gated sodium channels (VGSCs) and compete with tetrodotoxin for binding to the sodium conductance pore. Early efforts identified µ-conotoxins that preferentially blocked the skeletal muscle subtype (NaV1.4). However, the last decade witnessed a significant increase in the number of µ-conotoxins and the range of VGSC subtypes inhibited (NaV1.2, NaV1.3 or NaV1.7). Twenty µ-conotoxin sequences have been identified to date and structure-activity relationship studies of several of these identified key residues responsible for interactions with VGSC subtypes. Efforts to engineer-in subtype specificity are driven by in vivo analgesic and neuromuscular blocking activities. This review summarizes structural and pharmacological studies of µ-conotoxins, which show promise for development of selective blockers of NaV1.2, and perhaps also NaV1.1,1.3 or 1.7.