Flavonoids derived from medicinal plants as a COVID-19 treatment.

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) causes COVID-19 disease. Through its viral spike (S) protein, the virus enters and infects epithelial cells by utilizing angiotensin-converting enzyme 2 as a host cell's receptor protein. The COVID-19 pandemic had a profound impact on global public health and economies. Although various effective vaccinations and medications are now available to prevent and treat COVID-19, natural compounds derived from medicinal plants, particularly flavonoids, demonstrated therapeutic potential to treat COVID-19 disease. Flavonoids exhibit dual antiviral mechanisms: direct interference with viral invasion and inhibition of replication. Specifically, they target key viral molecules, particularly viral proteases, involved in infection. These compounds showcase significant immunomodulatory and anti-inflammatory properties, effectively inhibiting various inflammatory cytokines. Additionally, emerging evidence supports the potential of flavonoids to mitigate the progression of COVID-19 in individuals with obesity by positively influencing lipid metabolism. This review aims to elucidate the molecular structure of SARS-CoV-2 and the underlying mechanism of action of flavonoids on the virus. This study evaluates the potential anti-SARS-CoV-2 properties exhibited by flavonoid compounds, with a specific interest in their structure and mechanisms of action, as therapeutic applications for the prevention and treatment of COVID-19. Nevertheless, a significant portion of existing knowledge is based on theoretical frameworks and findings derived from in vitro investigations. Further research is required to better assess the effectiveness of flavonoids in combating SARS-CoV-2, with a particular emphasis on in vivo and clinical investigations.

The mechanisms underlying the role of Vitex agnus-castus in mastalgia.

Medicinal plants exert therapeutic effects or have beneficial healing functions on the human or animal body. Medicinal plants are widely used in traditional medicine as an interesting alternative and/or complementary to science-based medicine. Compared to chemical drugs, medicinal plants have a lower risk of side effects, are eco-friendly, and have cost-effective production. This encouraged researchers to extensively exploit them for their therapeutic use. One of the most well-known medicinal plants is Vitex agnus-castus L., which belongs to the Verbenaceae family. This shrub tree is mainly grown in tropical and sub-tropical regions. The parts of VAC, especially berries and leaves, contain essential oils, flavonoids, and diterpenes. Many medical benefits of VAC have already been reported, including mastalgia, regulating menstrual cycles and premenstrual complaints, and infertility. Respiratory and cardiovascular effects are also reported. In this review, we will analyze and characterize the known roles of VAC in mastalgia, as well as the mechanism of action reported in in vitro and/or in vivo studies, and show the potential for alternative therapeutic uses in mastalgia, also known as breast pain (Fig. 2, Ref. 40). Keywords: mastalgia, Vitex agnus-castus, therapy, traditional medicine.

Vasorelaxant Effects of the Vitex Agnus-Castus Extract.

This study was undertaken to describe and characterize the relaxing effects of the medicinal plant Vitex agnus-castus (VAC) extract on isolated rabbit arterial rings. The VAC extracts (VACE) were extracted with ethanol and tested in aorta rings (3-4 mm) of rabbits suspended in an organ bath (Krebs, 37°C, 95% O2/5% CO2) under a resting tension of 1 g to record isometric contractions. After the stabilization period (1-2 hours), contractions were induced by the addition of phenylephrine (0.5 µM) or high KCl (80 mM) and VACE was added on the plateau of the contractions. Experiments were performed to determine the effects and to get insights into the potential mechanism involved in VACE-induced relaxations. The cumulative addition of VACE (0.15-0.75 mg/mL) relaxed, in a concentration-dependent manner, the rabbit aorta rings precontracted either with phenylephrine- or with high KCl thus suggesting calcium channel blocking activities. The VACE effect appeared to be endothelium-dependent. The preincubation with L-NAME (the inhibitor of nitric oxide synthases (NOS)), ODQ (the selective inhibitor of guanylyl cyclase), and indomethacin (the cyclooxygenase inhibitor), downregulated VACE-induced relaxation of aorta rings precontracted with phenylephrine, whereas the bradykinin (stimulator of NOS) and zaprinast (phosphodiesterase inhibitor) further upregulated relaxant effects induced by VACE. These results revealed that the aorta relaxation effect of VACE was mainly endothelium-dependent and mediated by NO/cGMP and prostaglandins synthesis. This vasodilator effect of VACE may be useful to treat cardiovascular disorders, including hypertensive diseases.

Interactions between ACE2 and SARS-CoV-2 S Protein: Peptide Inhibitors for Potential Drug Developments Against COVID-19.

Angiotensin-converting enzyme (ACE) shares some homologies with ACE2. However, they are not inhibited by the same inhibitors, but both are associated primarily with the hypertensive disorder through the renin-angiotensin system (RAS). The principal activity of ACE2 is to metabolize Ang II into the vasodilatory Ang-(1-7). The ongoing COVID-19 pandemic caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has brought the ACE2 to the center of attention. This coronavirus uses the host cell ACE2 protein to enter and infect the epithelial cells. In light of the virus's entrance into human cells, the differences in the molecular basis of ACE2 among affected patients may cause their different responses to the virus. Many details about the specific interaction between the viral S protein and ACE2 are already reported. To date, some effective clinically approved vaccines are in use globally, and many others are under development, but no effective specific therapeutic drugs are available against COVID-19. Inhibitors, especially peptide inhibitors, have a great potential to be used for the treatment of COVID-19 and other possible emerging diseases caused by viral pathogens. As a result of the well-known viral protein structures and their host cell targets such as ACE2, antiviral peptides could be appropriately designed and optimized for therapeutic purposes. A better understanding of the structure and pathophysiology of the ACE2 receptor and the interplay between the viral S protein and ACE2 may help to find the solution for the virus treatment. This review summarizes the current understanding of S protein interaction with the ACE2 protein as a potential specific target against SARS-CoV-2 and strategies using peptides against COVID-19.

Klotho-Dependent Role of 1,25(OH)2D3 in the Brain.

The antiaging protein Klotho is encoded by the Klotho gene first identified as an 'aging suppressor', in mice. Klotho deficiency is involved in premature aging and early death, while its overexpression is related to longevity. Klotho is mostly expressed in the kidney, but also in the brain, and in other organs. Two forms of Klotho, the cell membrane and secreted form, have pleiotropic activities that include regulation of general metabolism, oxidative stress, and mineral metabolism that correlates with its effect on accelerating aging. Membrane Klotho serves as an obligate co-receptor for the fibroblast growth factor (FGF), while secreted Klotho plays its role as a humoral factor. Klotho protein participates in the regulation of several biological activities, including regulation of calcium-phosphate homeostasis and PTH as well as vitamin D metabolism. The active form of vitamin D, 1,25(OH)2D3 (1,25-dihydroxy-vitamin D3 = calcitriol), acts as a neurosteroid that participates in the regulation of multiple brain functions. It provides neuroprotection and suppresses oxidative stress, inhibits inflammation and inflammatory mediators, and stimulates various neurotrophins. Calcitriol is involved in many brain-related diseases, including multiple sclerosis, Alzheimer´s disease, Parkinson´s disease, and schizophrenia. This review covers the most recent advances in Klotho research and discusses Klotho-dependent roles of calcitriol in neuro-psycho-pathophysiology.

Molecular Characterization of SARS-CoV-2.

The coronavirus disease 2019 (COVID-19) is currently a new public health crisis threatening the world. This pandemic disease is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). The virus has been reported to be originated in bats, and by yet unknown intermediary animals were transmitted to humans in China 2019. The SARS-CoV-2 spreads faster than its two ancestors, the SARS-CoV and Middle East respiratory syndrome coronavirus (MERS-CoV) but has reduced fatality. At present, the SARS-CoV-2 has caused about 1.16 million deaths with more than 43.4 million confirmed cases worldwide, resulting in a serious threat to public health globally with yet uncertain impact. The disease is transmitted by inhalation or direct contact with an infected person. The incubation period ranges from 1 to 14 days. COVID-19 is accompanied by various symptoms, including cough and fatigue. In most people, the disease is mild, but in some other people, such as in the elderly and people with chronic diseases, it may progress from pneumonia to a multi-organ dysfunction. Many people are reported asymptomatic. The virus genome is sequenced, but new variants are reported. Numerous biochemical aspects of its structure and function are revealed. To date, no clinically approved vaccines and/or specific therapeutic drugs are available to prevent or treat COVID-19. However, there are reported intensive researches on the SARS-CoV-2 to potentially identify vaccines and/or drug targets, which may help to overcome the disease. In this review, we discuss recent advances in understanding the molecular structure of SARS-CoV-2 and its biochemical characteristics.

JAK2-mediated Intracellular Signaling.

Janus kinase-2 (JAK2) is a non-receptor tyrosine kinase that serves key roles as the intracellular signaling effector of the cytokine receptor, such as mediating effects of leptin, erythropoietin, interferon, and growth hormone. A lot of molecular underlying mechanisms of JAK2 participation are known, however, additional signaling mechanisms of its activation, regulation, and pleiotropic signaling roles are still being explored. Here, we review the current knowledge of JAK2-mediated cellular signaling at the molecular level. In the beginning, we will focus on the recent advances in JAK2 activation and regulation. A part of our review focuses on the JAK2 involvement in various diseases/conditions. Recent advances highlight the molecular regulatory mechanisms utilized by the JAK2 signaling, thus, enabling to consider alternative therapeutic strategies to treat various diseases/conditions mediated by JAK2 by using it as a therapeutic target.

Insight into the Mechanisms Underlying the Tracheorelaxant Properties of the Sideritis raeseri Extract.

Sideritis raeseri Boiss. and Heldr. (Lamiaceae), known as "mountain tea," is a native plant from the Mediterranean region, which is widely used in traditional medicine. This study evaluates the effects of the ethanol extract of Sideritis raeseri (SR) on airway smooth muscle activity and identifies the underlying mechanism. The S. raeseri extract (SRE) was extracted from air-dried parts of the shoot system of SR. The SRE (0.3-2 mg/mL) was tested in isolated rabbit tracheal rings, suspended in the organ bath, filled with Krebs solution, and bubbled with the carbogen mixture (95% O2/5% CO2) under a resting tension of 1 g in 37°C. In in vitro experiments, the SRE relaxed against acetylcholine-induced constriction in tracheal rings. Furthermore, SRE inhibited Ca2+-induced contractions in carbachol (CCh, 1 µM) as well as in the K+-depolarized trachea (80 mM). Our findings showed the NO/cGMP involvement in tracheorelaxant effects of SR. To this end, the effect of the SRE was potentiated by bradykinin (nitric oxide (NO) synthase activator, 100 nM), whereas it was inhibited by ODQ (inhibitor of NO-sensitive guanylyl cyclase, 10 µM) and L-NAME (NO synthase inhibitor, 100 µM), as well as indomethacin (cyclooxygenase inhibitor, 10 µM). These data suggest that the tracheorelaxant effect of the SRE is mediated at least partly by NO/cyclic guanosine monophosphate and cyclooxygenase-1-prostaglandin E2-dependent signaling. These findings indicate that the SRE may be used in various respiratory disorders.

Intracellular signaling of the AMP-activated protein kinase.

AMP-activated protein kinase (AMPK) is an essential cellular energy sensor that senses the cellular energy status and maintains cellular energy balance. The AMPK coordinates cellular and whole-body energy homeostasis through stimulating catabolic ATP-producing and suppressing anabolic ATP-consuming intracellular signaling pathways. AMPK induces autophagy and inhibits cell growth in response to starvation, a process that involves regulating certain intracellular signaling molecules. Recent advances demonstrated the AMPK to exert tumor suppressor activity realized through various signaling molecules by stimulating different cellular processes such as apoptosis, autophagy and cell growth and proliferation. AMPK can also be used to protect against metabolic syndrome. AMPK has previously been reported to be either directly or indirectly involved in the regulation of many different cellular transport proteins of high importance for cellular physiology and pathophysiology. Thus, AMPK provides a necessary link between cellular energy metabolism and cellular transport activities. A better understanding of the AMPK role in intracellular signaling under physiological and pathological conditions may represent a potential strategy for developing therapies for treating many different human diseases and disorders, in which AMPK plays a key role.

The Glycogen Synthase Kinase-3 in the Regulation of Ion Channels and Cellular Carriers.

Glycogen synthase kinase-3 (GSK-3) is a highly evolutionarily conserved and ubiquitously expressed serine/threonine kinase, an enzyme protein profoundly specific for glycogen synthase (GS). GSK-3 is involved in various cellular functions and physiological processes, including cell proliferation, differentiation, motility, and survival as well as glycogen metabolism, protein synthesis, and apoptosis. There are two isoforms of human GSK-3 (named GSK-3α and GSK-3ß) encoded by two distinct genes. Recently, GSK-3ß has been reported to function as a powerful regulator of various transport processes across the cell membrane. This kinase, GSK-3ß, either directly or indirectly, may stimulate or inhibit many different types of transporter proteins, including ion channel and cellular carriers. More specifically, GSK-3ß-sensitive cellular transport regulation involves various calcium, chloride, sodium, and potassium ion channels, as well as a number of Na+-coupled cellular carriers including excitatory amino acid transporters EAAT2, 3 and 4, high-affinity Na+ coupled glucose carriers SGLT1, creatine transporter 1 CreaT1, and the type II sodium/phosphate cotransporter NaPi-IIa. The GSK-3ß-dependent cellular transport regulations are a part of the kinase functions in numerous physiological and pathophysiological processes. Clearly, additional studies are required to examine the role of GSK-3ß in many other types of cellular transporters as well as further elucidating the underlying mechanisms of GSK-3ß-mediated cellular transport regulation.

Regulation of Ion Channels, Cellular Carriers and Na(+)/K(+)/ATPase by Janus Kinase 3.

Janus kinase-3 (JAK3), a tyrosine kinase, is expressed in a variety of tissues, including the brain and is involved in the signaling of cytokine receptors. JAK3 participates in numerous functions, such as cell survival and proliferation, neuroprotection, apoptosis and the cellular response to hypoxia and ischemia-reperfusion. This kinase further contributes to the signaling of hematopoietic cell cytokine receptors, activation of dendritic cells, maturation, and immune suppression as well as to cell volume regulation. Recently, JAK3 has been demonstrated to be an important regulator of transport processes across the plasma membrane. Either directly or indirectly JAK3 affects the expression of transport proteins, including various ion channels, a number of cellular carriers and the Na+/K+ pump. More specifically, JAK3 is involved in the regulation of various potassium, sodium, and chloride ion channels, a wide variety of Na+-coupled cellular carriers including the high-affinity Na+ coupled glucose transporter SGLT1, the excitatory amino acid transporters EAAT1, EAAT2, EAAT3 and EAAT4, the peptide transporters PepT1 and PepT2, CreaT1 and theNa+/K+-ATPase. Via these transporters this kinase plays a role in various physiological and pathophysiological processes. Additional research is needed to investigate the effects of JAK3 on other cellular transporters and the underlying mechanisms.

The Relevance of JAK2 in the Regulation of Cellular Transport.

Janus kinase-2 (JAK2) is a non-receptor tyrosine kinase signaling molecule that mediates the effects of various hormones and cytokines, including interferon, erythropoietin, leptin, and growth hormone. It also fosters tumor growth and modifies the activity of several nutrient transporters. JAK2 contributes to the regulation of the cell volume, protectS cells during energy depletion, proliferation, and aids the survival of tumor cells. Recently, JAK2 was identified as a powerful regulator of transport processes across the plasma membrane. Either directly or indirectly JAK2 may stimulate or inhibit transporter proteins, including ion channels, carriers and Na(+)/K(+) pumps. As a powerful regulator of transport mechanisms across the cell membrane, JAK2 regulates a wide variety of potassium, calcium, sodium and chloride ion channels, multiple Na+-coupled cellular carriers including EAAT1-4, NaPi-IIa, SGLT1, BoaT1, PepT1-2, CreaT1, SMIT1, and BGT1 as well as Na(+)/K(+)-ATPase. These cellular transport regulations contribute to various physiological and pathophysiological processes and thus exerting JAK2-sensitive effects. Future investigations will be important to determine whether JAK2 regulates cell-surface expression of other transporters and further elucidate underlying mechanisms governing JAK2 actions.

Upregulation of the creatine transporter Slc6A8 by Klotho.

BACKGROUND/AIMS: The transmembrane Klotho protein contributes to inhibition of 1,25(OH)2D3 formation. The extracellular domain of Klotho protein could function as an enzyme with e.g. ß-glucuronidase activity, be cleaved off and be released into blood and cerebrospinal fluid. Klotho regulates several cellular transporters. Klotho protein deficiency accelerates the appearance of age related disorders including neurodegeneration and muscle wasting and eventually leads to premature death. The main site of Klotho protein expression is the kidney. Klotho protein is also appreciably expressed in other tissues including chorioid plexus. The present study explored the effect of Klotho protein on the creatine transporter CreaT (Slc6A8), which participates in the maintenance of neuronal function and survival. METHODS: To this end cRNA encoding Slc6A8 was injected into Xenopus oocytes with and without additional injection of cRNA encoding Klotho protein. Creatine transporter CreaT (Slc6A8) activity was estimated from creatine induced current determined by two-electrode voltage-clamp. RESULTS: Coexpression of Klotho protein significantly increased creatine-induced current in Slc6A8 expressing Xenopus oocytes. Coexpression of Klotho protein delayed the decline of creatine induced current following inhibition of carrier insertion into the cell membrane by brefeldin A (5 µM). The increase of creatine induced current by coexpression of Klotho protein in Slc6A8 expressing Xenopus oocytes was reversed by ß-glucuronidase inhibitor (DSAL). Similarly, treatment of Slc6A8 expressing Xenopus oocytes with recombinant human alpha Klotho protein significantly increased creatine induced current. CONCLUSION: Klotho protein up-regulates the activity of creatine transporter CreaT (Slc6A8) by stabilizing the carrier protein in the cell membrane, an effect requiring ß-glucuronidase activity of Klotho protein.

Regulation of cellular transport by klotho protein.

The antiaging protein of Klotho is a transmembrane protein mainly expressed in the kidney, parathyroid glands and choroid plexus of the brain. The Klotho protein exists in two forms, a full-length membrane form and a soluble secreted form. The extracellular domain of Klotho can be enzymatically cleaved off and released into the systemic circulation where it acts as ß-glucuronidase and a hormone. Soluble Klotho can be found in the blood, cerebrospinal fluid, and the urine of mammals. Klotho deficiency results in early appearance of multiple age-related disorders and premature death, whereas overexpression of Klotho exerts the opposite effect. Klotho may influence cellular transport processes across the cell membrane by inhibiting calcitriol (1,25(OH) (2)D(3)), formation or by directly affecting transporter proteins, including ion channels, carriers and pumps. Accordingly, Klotho protein is a powerful regulator of transport mechanisms across the cell membrane. Klotho regulates diverse calcium and potassium ion channels, as well as several carriers including the Na(+)-coupled excitatory amino acid transporters EAAT3 and EAAT4, the Na(+)-coupled phosphate cotransporters, NaPi-IIa and NaPi-IIb, and a Na(+)/K(+)-ATPase. All those cellular transport regulations contribute in the aging suppressor role of Klotho. Future studies will help to determine if the Klotho protein regulates cell-surface expression of other transport proteins and is affecting underlying mechanisms.

AMPK-sensitive cellular transport.

The energy sensing AMP-activated protein kinase (AMPK) regulates cellular and whole-body energy balance through stimulating catabolic ATP-generating and suppressing anabolic ATP-consuming pathways thereby helping cells survive during energy depletion. The kinase has previously been reported to be either directly or indirectly involved in the regulation of several carriers, channels and pumps of high significance in cellular physiology. Thus AMPK provides a necessary link between cellular energy metabolism and cellular transport activity. Better understanding of the AMPK role in cellular transport offers a potential for improved therapies in various human diseases and disorders. In this review, we discuss recent advances in understanding the role and function of AMPK in transport regulation under physiological and pathological states.

Down-regulation of the Na+-coupled phosphate transporter NaPi-IIa by AMP-activated protein kinase.

BACKGROUND/AIMS: The Na(+)-coupled phosphate transporter NaPi-IIa is the main carrier accomplishing renal tubular phosphate reabsorption. It is driven by the electrochemical Na(+) gradient across the apical cell membrane, which is maintained by Na(+) extrusion across the basolateral cell membrane through the Na(+)/K(+) ATPase. The operation of NaPi-IIa thus requires energy in order to avoid cellular Na(+) accumulation and K(+) loss with eventual decrease of cell membrane potential, Cl(-) entry and cell swelling. Upon energy depletion, early inhibition of Na(+)-coupled transport processes may delay cell swelling and thus foster cell survival. Energy depletion is sensed by the AMP-activated protein kinase (AMPK), a serine/threonine kinase stimulating several cellular mechanisms increasing energy production and limiting energy utilization. The present study explored whether AMPK influences the activity of NAPi-IIa. METHODS: cRNA encoding NAPi-IIa was injected into Xenopus oocytes with or without additional expression of wild-type AMPK (AMPK(α1)-HA+AMPK(ß1)-Flag+AMPK(γ1)-HA), of inactive AMPK(αK45R) (AMPK(α1K45R)+AMPK(ß1)-Flag+AMPK(γ1)-HA) or of constitutively active AMPK(γR70Q) (AMPK(α1)-HA+AMPK(ß1)-Flag+AMPKγ1(R70Q)). NaPi-IIa activity was estimated from phosphate-induced current in dual electrode voltage clamp experiments. RESULTS: In NaPi-IIa-expressing, but not in water-injected Xenopus oocytes, the addition of phosphate (1 mM) to the extracellular bath solution generated a current (Ip), which was significantly decreased by coexpression of wild-type AMPK and of AMPK(γR70Q) but not of AMPK(αK45R). The phosphate-induced current in NaPi-IIa- and AMPK-expressing Xenopus ooocytes was significantly increased by AMPK inhibitor Compound C (20 µM). Kinetic analysis revealed that AMPK significantly decreased the maximal transport rate. CONCLUSION: The AMP-activated protein kinase AMPK is a powerful regulator of NaPi-IIa and thus of renal tubular phosphate transport. © 2013 S. Karger AG, Basel.

Significance of the anti-aging protein Klotho.

The Klotho gene was identified as an 'aging suppressor' in mice. Overexpression of the Klotho gene extends lifespan and defective Klotho results in rapid aging and early death. Both the membrane and secreted forms of Klotho have biological activity that include regulatory effects on general metabolism and a more specific effect on mineral metabolism that correlates with its effect on aging. Klotho serves as a co-receptor for fibroblast growth factor (FGF), but it also functions as a humoral factor that regulates cell survival and proliferation, vitamin D metabolism, and calcium and phosphate homeostasis and may serve as a potential tumor suppressor. Moreover, Klotho protects against several pathogenic processes in a FGF23-independent manner. These processes include cancer metastasis, vascular calcification, and renal fibrosis. This review covers the recent advances in Klotho research and discusses novel Klotho-dependent mechanisms that are clinically relevant in aging and age-related diseases.

Upregulation of Na-coupled glucose transporter SGLT1 by Tau tubulin kinase 2.

The Tau-tubulin-kinase 2 (TTBK2) is a serine/threonine kinase expressed in various tissues including tumors. Up-regulation of TTBK2 increases resistance of tumor cells against antiangiogenic treatment and confers cell survival. Tumor cell survival critically depends on cellular uptake of glucose, which is partially accomplished by SGLT1 (SLC5A1) mediated Na(+)-coupled glucose transport. The present study explored whether TTBK2 participates in the regulation of SGLT1 activity. To this end, electrogenic glucose transport was determined in Xenopus oocytes expressing SGLT1 with or without wild-type TTBK2, truncated TTBK2([1-450]) or kinase inactive mutants TTBK2-KD and TTBK2-KD([1-450]). TTBK2, but not TTBK2([1-450]), TTBK2-KD or TTBK2-KD([1-450]), increased membrane carrier protein abundance and electrogenic glucose transport capacity in SGLT1-expressing Xenopus oocytes. Thus TTBK2 is a completely novel regulator of Na(+)-coupled glucose transport.

Downregulation of the osmolyte transporters SMIT and BGT1 by AMP-activated protein kinase.

The myoinositol transporter SMIT (SLC5A3) and the betaine/γ-aminobutyric acid (GABA) transporter BGT1 (SLC6A12) accomplish cellular accumulation of organic osmolytes and thus contribute to cell volume regulation. Challenges of cell volume constancy include energy depletion, which compromises the function of the Na(+)/K(+) ATPase leading to cellular Na(+) accumulation and subsequent cell swelling. Energy depletion is sensed by AMP-activated protein kinase (AMPK). The present study explored whether AMPK influences the activity of SMIT and BGT1. To this end, cRNA encoding SMIT or BGT1 was injected into Xenopus oocytes with and without additional injection of wild type AMPK (AMPKα1+AMPKß1+AMPKγ1), of constitutively active (γR70Q)AMPK (AMPKα1+AMPKß1+(R70Q)AMPKγ1) or of catalytically inactive (αK45R)AMPK ((K45R)AMPKα1+AMPKß1+AMPKγ1). Substrate-induced current in dual electrode voltage-clamp experiments was taken as measure of osmolyte transport. As a result, in SMIT-expressing, but not in water-injected Xenopus oocytes, myoinositol, added to the extracellular bath, generated a current (I(SMIT)), which was half maximal (K(M)) at ≈7.2µM myoinositol concentration. Furthermore, in BGT1-expressing, but not in water-injected Xenopus oocytes, GABA added to the bath generated a current (I(GABA)), which was half maximal (K(M)) at ≈0.5mM GABA concentration. Coexpression of AMPK and of (γR70Q)AMPK but not of (αK45R)AMPK significantly decreased I(SMIT) and I(GABA). AMPK decreased the respective maximal currents without significantly modifying the respective K(M). In conclusion, the AMP-activated kinase AMPK is a powerful regulator of the organic osmolyte transporters SMIT and BGT1 and thus interacts with cell volume regulation.

Regulation of the glutamate transporters by JAK2.

The Janus-activated kinase-2 JAK2 is involved in the signaling of leptin and erythropoietin receptors and mediates neuroprotective effects of the hormones. In theory, JAK2 could be effective through modulation of the glutamate transporters, carriers accounting for the clearance of glutamate released during neurotransmission. The present study thus elucidated the effect of JAK2 on the glutamate transporters EAAT1, EAAT2, EAAT3 and EAAT4. To this end, cRNA encoding the carriers was injected into Xenopus oocytes with or without cRNA encoding JAK2 and glutamate transport was estimated from glutamate induced current (I(glu)). I(glu) was observed in Xenopus oocytes expressing EAAT1 or EAAT2 or EAAT3 or EAAT4, but not in water injected oocytes. Coexpression of JAK2 resulted in an increase of I(glu) by 83% (EAAT1), 67% (EAAT2), 42% (EAAT3) and 126% (EAAT4). As shown for EAAT4 expressing Xenopus oocytes, the effect of JAK2 was mimicked by gain of function mutation (V617F)JAK2 but not by the inactive mutant (K882E)JAK2. Incubation with JAK2 inhibitor AG490 (40 µM) resulted in a gradual decrease of I(glu) by 53%, 79% and 92% within 3, 6 and 24 hours. Confocal microscopy and chemiluminescence analysis revealed that JAK2 coexpression increased EAAT4 protein abundance in the cell membrane. Disruption of transcription did not appreciably modify the up-regulation of I(glu) in EAAT4 expressing oocytes. The decay of I(glu) following inhibition of carrier insertion with brefeldin A was similar in oocytes expressing EAAT4 + JAK2 and oocytes expressing EAAT4 alone, indicating that JAK2 did not appreciably affect carrier retrieval from the membrane. In conclusion, JAK2 is a novel powerful regulator of glutamate transporters and thus participates in the protection against excitotoxicity.