Browsing by Author "Pupure, Jolanta"
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Item Comparative study of taurine and tauropyrone : GABA receptor binding, mitochondrial processes and behaviour(2011-02) Dzirkale, Zane; Pupure, Jolanta; Rumaks, Juris; Svirskis, Simons; Vanina, Marija; Mezhapuke, Rudolfs; Sile, Velga; Fernandes, Maria Augusta; Duburs, Gunars; Klusa, VijaObjectives Taurine, a sulfur-containing amino acid, has high hydrophilicity and is poorly absorbed. Tauropyrone, a taurine-containing 1,4-dihydropyridine derivative, is suggested to have greater activity than taurine owing to improved physicochemical properties that facilitate delivery of the compound to target cells. The aim of this study was to determine whether the 1,4-dihydropyridine moiety in tauropyrone improves the pharmacological efficacy of taurine in vitro and in vivo. Methods The effects of taurine and tauropyrone, as well as of the 1,4-dihydropyridine moiety were compared in in-vitro experiments to determine the binding to GABA receptors and influence on mitochondrial processes (isolated rat liver mitochondria), and in in-vivo tests to assess the influence on behavioural effects caused by the GABA-A receptor ligands, bicuculline, diazepam and ethanol. Key findings Unlike taurine, tauropyrone did not display binding activity for the GABA-A receptor, and only taurine (but not tauropyrone) at low doses (0.1, 1.0 and 10 mg/kg) antagonised the bicuculline-induced convulsion effect. Taurine and tauropyrone had no effect on diazepam myorelaxing action, and they both exerted a comparable 'anti-ethanol' effect (shortening of the ethanol-sleeping time). Taurine and tauropyrone did not influence processes of mitochondrial bioenergetics. Conclusions The action of tauropyrone at the level of the GABA-A receptor differs qualitatively from that of taurine, probably because of its 1,4-dihydropyridine moiety, which may hinder access to the GABA-A receptor GABA site. Tauropyrone does not show improved pharmacological efficacy in in-vitro and in-vivo studies in comparison with taurine.Item Mildronate and its Neuroregulatory Mechanisms : Targeting the Mitochondria, Neuroinflammation, and Protein Expression(2013-08-04) Beitnere, Ulrika; Pupure, Jolanta; Isajevs, Sergejs; Rumaks, Juris; Svirskis, Simons; Dzirkale, Zane; Kalvinsh, IvarsThis review for the first time summarizes the data obtained in the neuropharmacological studies of mildronate, a drug previously known as a cardioprotective agent. In different animal models of neurotoxicity and neurodegenerative diseases, we demonstrated its neuroprotecting activity. By the use of immunohistochemical methods and Western blot analysis, as well as some selected behavioral tests, the new mechanisms of mildronate have been demonstrated: a regulatory effect on mitochondrial processes and on the expression of nerve cell proteins, which are involved in cell survival, functioning, and inflammation processes. Particular attention is paid to the capability of mildronate to stimulate learning and memory and to the expression of neuronal proteins involved in synaptic plasticity and adult neurogenesis. These properties can be useful in neurological practice to protect and treat neurological disorders, particularly those associated with neurodegeneration and a decline in cognitive functions.Item Mildronate's protective effects in the peripheral nervous system : Stavudine-induced neuropathy and formalin-induced inflammation(2010-01-01) Pupure, Jolanta; Rumaks, Juris; Isajevs, Sergejs; Korzakova, Olga; Puncule, Jelena; Svirskis, Simons; Kalviņš, Ivars; Kluša, VijaMildronate, previously known as a cardioprotective drug, recently was found to normalise mitochondrial processes by preventing the dysfunction of complex I in rat liver mitochondria. Previously we have shown also the ability of mildronate to prevent pathologies in the central nervous system by normalizing the expression of different signalling molecules in brain tissue. This allowed us to suggest that mildronate may possess a beneficial role also in peripheral nervous system pathologies. The present study was designed to assess the peripheral tissue damage caused by anti-HIV drug stavudine, as well as pain and inflammation caused by formalin. For this demonstration, we investigated the influence of mildronate: (1) on decreased myelin expression and increased neuron degeneration in rat sciatic nerve tissue caused by stavudine; and (2) on formalin-induced inflammation in mice. We found that mildronate protected the stavudine-induced degeneration of neurons in rat peripheral sciatic nerve without a significant influence on demyelination. In a formalin test, mildronate showed anti-inflammatory action comparable to that of indomethacin, a reference drug. The present results show that mildronate is capable of regulating peripheral nerve damage and peripheral inflammatory responses. We suggest that the multifunctional effects of mildronate can be attributed to its ability to regulate mitochondrial processes. The obtained data indicate protective effects of mildronate in different peripheral neurological pathologies.Item Neuroprotective properties of mildronate, a small molecule, in a rat model of parkinson's disease(2010-11) Klusa, Vija Z.; Isajevs, Sergejs; Svirina, Darja; Pupure, Jolanta; Beitnere, Ulrika; Rumaks, Juris; Svirskis, Simons; Jansone, Baiba; Dzirkale, Zane; Muceniece, Ruta; Kalvinsh, Ivars; Vinters, Harry V.Previously, we have found that mildronate [3-(2,2,2-trimethylhydrazinium) propionate dihydrate], a small molecule with charged nitrogen and oxygen atoms, protects mitochondrial metabolism that is altered by inhibitors of complex I and has neuroprotective effects in an azidothymidine-neurotoxicity mouse model. In the present study, we investigated the effects of mildronate in a rat model of Parkinson's disease (PD) that was generated via a unilateral intrastriatal injection of the neurotoxin 6-hydroxydopamine (6-OHDA). We assessed the expression of cell biomarkers that are involved in signaling cascades and provide neural and glial integration: the neuronal marker TH (tyrosine hydroxylase); ubiquitin (a regulatory peptide involved in the ubiquitin-proteasome degradation system); Notch-3 (a marker of progenitor cells); IBA-1 (a marker of microglial cells); glial fibrillary acidic protein, GFAP (a marker of astrocytes); and inducible nitric oxide synthase, iNOS (a marker of inflammation). The data show that in the 6-OHDA-lesioned striatum, mildronate completely prevented the loss of TH, stimulated Notch-3 expression and decreased the expression of ubiquitin, GFAP and iNOS. These results provide evidence for the ability of mildronate to control the expression of an array of cellular proteins and, thus, impart multi-faceted homeostaticmechanisms in neurons and glial cells in a rat model of PD. We suggest that the use of mildronate provides a protective effect during the early stages of PD that can delay or halt the progression of this neurodegenerative disease.Item Search for stroke-protecting agents in endothelin-1-induced ischemic stroke model in rats(2012) Rumaks, Juris; Pupure, Jolanta; Svirskis, Simons; Isajevs, Sergejs; Duburs, Gunars; Kalvinsh, Ivars; Klusa, VijaBackground and Objective. Ischemic stroke may initiate a reperfusion injury leadingto brain damage cascades where inflammatory mechanisms play a major role. Therefore, thenecessity for the novel stroke-protecting agents whose the mechanism of action is focused on their anti-inflammatory potency is still on the agenda for drug designers. Our previous studies demonstrated that cerebrocrast (a 1,4-dihydropyridine derivative) and mildronate (a representative of the aza-butyrobetaine class) possessed considerable anti-inflammatory and neuroprotective properties in different in vitro and in vivo model systems.The present study investigated their stroke-protecting ability in an endothelin-1 (ET-1)-induced ischemic stroke model in rats. Material and Methods. Male Wistar rats were pretreated (for 7 days, per os) with cerebrocrast (0.1 mg/kg), mildronate (100 mg/kg), or their combination, followed by the intracerebral injection of ET-1. Functional and behavioral tests were carried out up to 14 days after the ET-1 injection. Ex vivo, the number of degenerated neurons and the infarction size in the cerebral cortical tissue were assessed histologically. Results. Cerebrocrast and mildronate effectively normalized ET-1-induced disturbances in neurological status, improved the muscle tone, and decreased the number of degenerated cortical cells. Both drugs also reduced the infarction size, and cerebrocrast showed at least a 2-fold higher activity than mildronate. The combination of both drugs did not cause a more pronounced effect in comparison with the action of drugsadministered separately. Conclusions. The 1,4-dihydropyridine and aza-butyrobetaine structures may serve for the design of novel stroke-protecting agents to prevent severe neurological poststroke consequences.