adenosine-kinase and Nervous-System-Diseases

The endogenous neuromodulator adenosine controls and integrates a wide range of brain functions. Consequently, dysfunction of the adenosine system is involved in pathologies ranging from epilepsy to neurodegenerative disorders and psychiatric conditions. The adenosine system has therefore been recognized as a prime target for the development of new therapeutics for neurological diseases. This review covers the upstream and downstream targets of adenosinergic neurotransmission and provides the neurochemical rationale for the development of adenosine receptor modulating drugs (downstream) and inhibitors of adenosine kinase, the key upstream regulator of ambient levels of adenosine. Due to the unique role of adenosine to integrate and fine-tune glutamatergic and dopaminergic neurotransmission, adenosine-regulating agents have the potential to modify a wide range of downstream effects. Thus, adenosine-based therapies are rapidly evolving in preclinical and clinical studies.

Topics: Adenosine; Adenosine Kinase; Animals; Brain; Clinical Trials as Topic; Drug Delivery Systems; Drug Evaluation, Preclinical; Humans; Nervous System Diseases; Receptor, Adenosine A1; Receptor, Adenosine A2A

Epilepsy disease is characterized by the neuronal dysfunction or abnormal neuronal activity of the brain which is regulated by astrocytes. These are glial cells and found to be the major regulators of the brain which are guided by the occurrence of adenosine kinase (ADK) enzyme in the central nervous system (CNS). During the normal physiological environment, ADK maintains the level of adenosine in the CNS. Dysfunction of ADK levels results in accumulation of adenosine levels in the CNS that leads to the pathophysiology of the brain such as astrogliosis which is a pathological hallmark of epileptic seizures. Vicine, an alkaloid glycoside in bitter gourd juice (Momordica charantia) is found to be toxic to the human system if the bitter gourd juice is consumed more. This compound inhibits ADK enzyme activity to lead epilepsy and seizure. Here, the toxic effect of vicine targeting ADK using computational predictions was investigated. The 3-dimensional structure of ADK has been constructed using I-Tasser, which has been refined by ModRefiner, GalaxyRefine, and 3D refine and it was endorsed using PROCHECK, ERRAT, and VADAR. 3D structure of the ligand molecule has been obtained from PubChem. Molecular docking has been achieved using AutoDock 4.2 software, from which the outcome showed the effective interaction between vicine and ADK, which attains binding free energy (∆G) of - 4.13 kcal/mol. Vicine molecule interacts with the active region ARG 149 of ADK and inhibits the functions of ADK that may cause imbalance in energy homeostasis. Also, pre-ADMET results robustly propose in which vicine possesses toxicity, and meanwhile, from the Ames test, it was shown as mutagenic. Hence, the results from our study suggest that vicine was shown to be toxic that suppresses the ADK activity to undergo pathological conditions in the neuronal junctions to lead epilepsy.

Topics: Adenosine Kinase; Alkaloids; Animals; Drug Development; Glucosides; Glycosides; Humans; Mice; Molecular Docking Simulation; Momordica charantia; Nervous System Diseases; Protein Structure, Secondary; Pyrimidinones; Rats; Toxins, Biological

Protective mechanisms of the brain may reduce the extent of injury after focal cerebral ischemia. Here, we explored in a mouse model of focal cerebral ischemia potential synergistic neuroprotective effects of two mediators of neuroprotection: (i) neuronal or glial precursor cells and (ii) the inhibitory neuromodulator adenosine. Embryonic stem (ES) cells, engineered to release adenosine by biallelic disruption of the adenosine kinase gene, and respective wild-type cells were induced to differentiate into either neural or glial precursor cells and were injected into the striatum of mice 1 week before middle cerebral artery occlusion. All stem cell-derived graft recipients were characterized by a significant reduction in infarct volume, an effect that was augmented by the release of adenosine. Neuroprotection was strongest in adenosine-releasing glial precursor cell recipients, which were characterized by an 85% reduction of the infarct area. Graft-mediated neuroprotection correlated with a significant improvement of general and focal neurologic scores. Histologic analysis before and after ischemia revealed clusters of implanted cells within the striatum of all treated mice. We conclude that ES cell derived adenosine-releasing brain implants provide neuroprotection by synergism of endogenous precursor cell-mediated effects and paracrine adenosine release.

Topics: Adenosine; Adenosine Kinase; Alleles; Animals; Brain Ischemia; Cerebral Infarction; Male; Mice; Mice, Inbred C57BL; Mice, Knockout; Nervous System Diseases; Neurons; Stem Cell Transplantation