Role of NKCC1 Activity in Glioma K+ Homeostasis and Cell Growth: New Insights With the Bumetanide-Derivative STS66.

Introduction: Na+-K+-2Cl- cotransporter isoform 1 (NKCC1) is important in regulating intracellular K+ and Cl- homeostasis and cell volume. In this study, we investigated a role of NKCC1 in regulating glioma K+ influx and proliferation in response to apoptosis inducing chemotherapeutic drug temozolomide (TMZ). The efficacy of a new bumetanide (BMT)-derivative NKCC1 inhibitor STS66 [3-(butylamino)-2-phenoxy-5-[(2, 2, 2-trifluoroethylamino) methyl] benzenesulfonamide] in blocking NKCC1 activity was compared with well-established NKCC1 inhibitor BMT. Methods: NKCC1 activity in cultured mouse GL26 and SB28-GFP glioma cells was measured by Rb+ (K+) influx. The WNK1-SPAK/OSR1-NKCC1 signaling and AKT/ERK-mTOR signaling protein expression and activation were assessed by immunoblotting. Cell growth was determined by bromodeoxyuridine (BrdU) incorporation assay, MTT proliferation assay, and cell cycle analysis. Impact of STS66 and BMT on cell Rb+ influx and growth was measured in glioma cells treated with or without TMZ. Results: Rb+ influx assay showed that 10 µM BMT markedly decreased the total Rb+ influx and no additional inhibition detected at >10 µM BMT. In contrast, the maximum effects of STS66 on Rb+ influx inhibition were at 40-60 µM. Both BMT and STS66 reduced TMZ-mediated NKCC1 activation and protein upregulation. Glioma cell growth can be reduced by STS66. The most robust inhibition of glioma growth, cell cycle, and AKT/ERK signaling was achieved by the TMZ + STS66 treatment. Conclusion: The new BMT-derivative NKCC1 inhibitor STS66 is more effective than BMT in reducing glioma cell growth in part by inhibiting NKCC1-mediated K+ influx. TMZ + STS66 combination treatment reduces glioma cell growth via inhibiting cell cycle and AKT-ERK signaling.

Functional characterization of novel bumetanide derivatives for epilepsy treatment.

Temporal lobe epilepsy (TLE) is the most common type of focal epilepsies, affecting approximately 35 million people worldwide. Despite the introduction of numerous novel antiepileptic drugs during the last decades, the proportion of patients with therapy-resistant TLE is still high. As an impaired cellular chloride homeostasis appears involved in disease pathophysiology, bumetanide, an antagonist to Na-K-Cl cotransporters, gained interest as potential therapeutic option. However, bumetanide induces a strong diuretic effect and displays poor penetration across the blood-brain barrier (BBB). To reduce these unwanted effects, we modified the already described BUM690 by exchanging the allyl-into a trifluoro-ethyl group to yield BUM532. Furthermore, we exchanged the nitrogen for oxygen in the trifluoro-ethyl group to yield BUM97. In the intrahippocampal kainic acid mouse model of TLE BUM532 ±â€¯phenobarbital (PB), bumetanide ±â€¯PB and PB alone significantly reduced hippocampal paroxysmal discharges (HPDs) but not spike trains. By contrast, treatment with BUM97 suppressed HPDs as well as spike trains dose-dependently, more pronounced compared to the other tested compounds and exerted a synergistic anticonvulsant effect with PB. Moreover, at higher doses BUM97 achieved long-lasting reduction of spike trains. In pentylenetetrazole-induced acute seizures only BUM532 combined with a sub-effective dose of PB increased the seizure threshold. No diuretic effects were observed at any dose of the three derivatives. Our data demonstrate the successful optimization of the pharmacological profile of bumetanide and the potential of the improved derivative BUM97 for the treatment of therapy-resistant TLE, in particular in combinatorial drug regimens with a GABA mimetic.

Impaired chloride homeostasis in epilepsy: Molecular basis, impact on treatment, and current treatment approaches.

Epilepsies represent one of the most common neurological diseases worldwide. They are characterized by recurrent spontaneous seizures with severe impact on a patient's life. An imbalance in excitatory and inhibitory signalling is considered the main underlying pathophysiological mechanism. Therefore, GABA-mimetic drugs, strengthening the main inhibitory signalling system in the CNS, are frequently used as antiepileptic or anticonvulsant drugs. However, the therapeutic effect of such treatment depends on the chloride gradient along the plasma membrane. Impairment of chloride homeostasis, caused by alterations in the functional balance of chloride transporters, was implicated in the pathophysiology of epilepsy and numerous other diseases. Breakdown or even inversion of the chloride gradient may result in ineffective or in worst cases proconvulsant effects of GABA-mimetics. Unfortunately, such situations are reported in considerable number. Consequently, bumetanide, an inhibitor of Na-K-Cl cotransporters gained interest as potential add-on therapy re-establishing the chloride gradient and thereby the hyperpolarizing effects of GABA-mimetic drugs. Indeed, preclinical studies yielded encouraging results, especially when applied in combination with GABA-mimetics in epilepsy models. However, bumetanide induces a strong diuretic effect and displays poor penetration across the blood-brain barrier, two adverse features for chronic antiepileptic treatment. Therefore, new compounds overcoming these limitations are under development. This review focuses on alterations in chloride homeostasis and its underlying molecular mechanisms in epilepsy, on the potential impact of impaired chloride homeostasis on the treatment of epilepsy and on concepts to overcome this problem including recent development of bumetanide derivatives with improved pharmacological profile.

A Novel Na+-K+-Cl- Cotransporter 1 Inhibitor STS66* Reduces Brain Damage in Mice After Ischemic Stroke.

Background and Purpose- Inhibition of brain NKCC1 (Na+-K+-Cl- cotransporter 1) with bumetanide (BMT) is of interest in ischemic stroke therapy. However, its poor brain penetration limits the application. In this study, we investigated the efficacy of 2 novel NKCC1 inhibitors, a lipophilic BMT prodrug STS5 (2-(Dimethylamino)ethyl 3-(butylamino)-4-phenoxy-5-sulfamoyl-benzoate;hydrochloride) and a novel NKCC1 inhibitor STS66 (3-(Butylamino)-2-phenoxy-5-[(2,2,2-trifluoroethylamino)methyl]benzenesulfonamide), on reducing ischemic brain injury. Methods- Large-vessel transient ischemic stroke in normotensive C57BL/6J mice was induced with 50-min occlusion of the middle cerebral artery and reperfusion. Focal, permanent ischemic stroke in angiotensin II (Ang II)-induced hypertensive C57BL/6J mice was induced by permanent occlusion of distal branches of middle cerebral artery. A total of 206 mice were randomly assigned to receive vehicle DMSO, BMT, STS5, or STS66. Results- Poststroke BMT, STS5, or STS66 treatment significantly decreased infarct volume and cerebral swelling by ≈40% to 50% in normotensive mice after transient middle cerebral artery occlusion, but STS66-treated mice displayed better survival and sensorimotor functional recovery. STS5 treatment increased the mortality. Ang II-induced hypertensive mice exhibited increased phosphorylatory activation of SPAK (Ste20-related proline alanine-rich kinase) and NKCC1, as well as worsened infarct and neurological deficit after permanent distal middle cerebral artery occlusion. Conclusions- The novel NKCC1 inhibitor STS66 is superior to BMT and STS5 in reducing ischemic infarction, swelling, and neurological deficits in large-vessel transient ischemic stroke, as well as in permanent focal ischemic stroke with hypertension comorbidity.

The bumetanide prodrug BUM5, but not bumetanide, potentiates the antiseizure effect of phenobarbital in adult epileptic mice.

OBJECTIVE: The loop diuretic bumetanide has been reported to potentiate the antiseizure activity of phenobarbital in rodent models of neonatal seizures, most likely as a result of inhibition of the chloride importer Na-K-Cl cotransporter isoform 1 (NKCC1) in the brain. In view of the intractability of neonatal seizures, the preclinical findings prompted a clinical trial in neonates on bumetanide as an add-on to phenobarbital, which, however, had to be terminated because of ototoxicity and lack of efficacy. We have recently shown that bumetanide penetrates only poorly into the brain, so that we developed lipophilic prodrugs such as BUM5, the N,N-dimethylaminoethylester of bumetanide, which penetrate more easily into the brain and are converted to bumetanide. METHODS: In the present study, we used a new strategy to test whether BUM5 is more potent than bumetanide in potentiating the antiseizure effect of phenobarbital. Adult mice were made epileptic by pilocarpine, and the antiseizure effects of bumetanide, BUM5, and phenobarbital alone or in combination were determined by the maximal electroshock seizure threshold test. RESULTS: In nonepileptic mice, only phenobarbital exerted seizure threshold-increasing activity, and this was not potentiated by the NKCC1 inhibitors. In contrast, a marked potentiation of phenobarbital by BUM5, but not bumetanide, was determined in epileptic mice. SIGNIFICANCE: Thus, bumetanide is not capable of potentiating phenobarbital's antiseizure effect in an adult mouse model, which, however, can be overcome by using the prodrug BUM5. These data substantiate that BUM5 is a promising tool compound for target validation and proof-of-concept studies on the role of NKCC1 in brain diseases.

A Novel Genistein Prodrug: Design, Synthesis and Bioactivity on Mouse RAW264.7 Macrophages.

Genistein, a naturally occurring isoflavone, possesses many beneficial health effects. To improve the bioactivity of the natural compound, we designed and synthesized the genistein prodrug FEHH6-1. In the present study, we evaluated the biological effects of FEHH6-I on mouse RAW264.7 macrophages and compared them with those obtained with the parent drug genistein. The characteristics of FEHH6-1 were determined by melting point, nuclear magnetic resonance spectroscopy (NMR), and mass spectrometric analysis. The effects of FEHH6-I on cell proliferation, apoptosis, and pro-inflammatory cytokine expression were monitored by XTT-assay, Annexin-V/7-AAD staining, Western blotting, and ELISA. FEHH6-1 showed NMR spectra and relative molecular mass in agreement with the designed structure. In mouse RAW264.7 macrophages, FEHH6-1 inhibited proliferation, induced apoptotic cell death and blocked interleukin 6 and tumor necrosis factor alpha synthesis. At low concentrations, FEHH6-1 induced phosphorylation of AKT1, a kinase involved in cell proliferation and survival. Our data demonstrate that the genistein prodrug FEHH6-1 is a bioactive molecule but its solubility and therefore also its efficacy was significantly lower compared with genistein.