Browsing by Author "Costa, Blaise M."

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    Cranial manipulation affects cholinergic pathway gene expression in aged rats
    Anandakrishnan, Ramu; Tobey, Hope; Nguyen, Steven; Sandoval, Osscar; Klein, Bradley G.; Costa, Blaise M. (De Gruyter, 2022-01-10)
    Context: Age-dependent dementia is a devastating disorder afflicting a growing older population. Although pharmacological agents improve symptoms of dementia, age-related comorbidities combined with adverse effects often outweigh their clinical benefits. Therefore, nonpharmacological therapies are being investigated as an alternative. In a previous pilot study, aged rats demonstrated improved spatial memory after osteopathic cranial manipulative medicine (OCMM) treatment. Objectives: In this continuation of the pilot study, we examine the effect of OCMM on gene expression to elicit possible explanations for the improvement in spatialmemory. Methods: OCMM was performed on six of 12 elderly rats every day for 7 days. Rats were then euthanized to obtain the brain tissue, from which RNA samples were extracted. RNA from three treated and three controls were of sufficient quality for sequencing. These samples were sequenced utilizing next-generation sequencing from Illumina NextSeq. The Cufflinks software suite was utilized to assemble transcriptomes and quantify the RNA expression level for each sample. Results: Transcriptome analysis revealed that OCMM significantly affected the expression of 36 genes in the neuronal pathway (false discovery rate [FDR] <0.004). The top five neuronal genes with the largest-fold change were part of the cholinergic neurotransmission mechanism, which is known to affect cognitive function. In addition, 39.9% of 426 significant differentially expressed (SDE) genes (FDR<0.004) have been previously implicated in neurological disorders. Overall, changes in SDE genes combined with their role in central nervous system signaling pathways suggest a connection to previously reported OCMM-induced behavioral and biochemical changes in aged rats. Conclusions: Results from this pilot study provide sufficient evidence to support a more extensive study with a larger sample size. Further investigation in this direction will provide a better understanding of the molecular mechanisms of OCMM and its potential in clinical applications. With clinical validation, OCMM could represent a much-needed low-risk adjunct treatment for age-related dementia including Alzheimer's disease.
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    Differential regulation of STP, LTP and LTD by structurally diverse NMDA receptor subunit-specific positive allosteric modulators
    France, G.; Volianskis, R.; Ingram, R.; Bannister, N.; Rotharmel, R.; Irvine, M. W.; Fang, G.; Burnell, E. S.; Sapkota, K.; Costa, Blaise M.; Chopra, D. A.; Dravid, S. M.; Michael-Titus, A. T.; Monaghan, D. T.; Georgiou, J.; Bortolotto, Z. A.; Jane, D. E.; Collingridge, G. L.; Volianskis, A. (Pergamon-Elsevier, 2022-01-01)
    Different types of memory are thought to rely on different types of synaptic plasticity, many of which depend on the activation of the N-Methyl-D Aspartate (NMDA) subtype of glutamate receptors. Accordingly, there is considerable interest in the possibility of using positive allosteric modulators (PAMs) of NMDA receptors (NMDARs) as cognitive enhancers. Here we firstly review the evidence that NMDA receptor-dependent forms of synaptic plasticity: short-term potentiation (STP), long-term potentiation (LTP) and long-term depression (LTD) can be pharmacologically differentiated by using NMDAR ligands. These observations suggest that PAMs of NMDAR function, depending on their subtype selectivity, might differentially regulate STP, LTP and LTD. To test this hypothesis, we secondly performed experiments in rodent hippocampal slices with UBP714 (a GluN2A/2B preferring PAM), CIQ (a GluN2C/D selective PAM) and UBP709 (a pan-PAM that potentiates all GluN2 subunits). We report here, for the first time, that: (i) UBP714 potentiates sub-maximal LTP and reduces LTD; (ii) CIQ potentiates STP without affecting LTP; (iii) UBP709 enhances LTD and decreases LTP. We conclude that PAMs can differentially regulate distinct forms of NMDAR-dependent synaptic plasticity due to their subtype selectivity.
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    A glutamate concentration-biased allosteric modulator potentiates NMDA-induced ion influx in neurons
    Costa, Blaise M.; Kwapisz, Lina Cortes; Mehrkens, Brittney; Bledsoe, Douglas N.; Vacca, Bryanna N.; Johnston, Tullia V.; Razzaq, Rehan; Manickam, Dhanasekaran; Klein, Bradley G. (Wiley, 2021-10-01)
    Precisely controlled synaptic glutamate concentration is essential for the normal function of the N-methyl D-aspartate (NMDA) receptors. Atypical fluctuations in synaptic glutamate homeostasis lead to aberrant NMDA receptor activity that results in the pathogenesis of neurological and psychiatric disorders. Therefore, glutamate concentration-dependent NMDA receptor modulators would be clinically useful agents with fewer on-target adverse effects. In the present study, we have characterized a novel compound (CNS4) that potentiates NMDA receptor currents based on glutamate concentration. This compound alters glutamate potency and exhibits no voltage-dependent effect. Patch-clamp electrophysiology recordings confirmed agonist concentration-dependent changes in maximum inducible currents. Dynamic Ca2+ and Na+ imaging assays using rat brain cortical, striatal and cerebellar neurons revealed CNS4 potentiated ion influx through native NMDA receptor activity. Overall, CNS4 is novel in chemical structure, mechanism of action and agonist concentration-biased allosteric modulatory effect. This compound or its future analogs will serve as useful candidates to develop drug-like compounds for the treatment of treatment-resistant schizophrenia and major depression disorders associated with hypoglutamatergic neurotransmission.
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    Pharmacology of a novel biased allosteric modulator for NMDA receptors
    Kwapisz, Lina (Virginia Tech, 2021-06-07)
    NMDA glutamate receptor is a ligand-gated ion channel that mediates a major component of excitatory neurotransmission in the central nervous system (CNS). NMDA receptors are activated by simultaneous binding of two different agonists, glutamate and glycine/ D-serine1. With aging, glutamate concentration gets altered, giving rise to glutamate toxicity that contributes to age-related pathologies like Parkinson's disease, Alzheimer's disease, amyotrophic lateral sclerosis, and dementia88,95. Some treatments for these conditions include NMDA receptor blockers like memantine130. However, when completely blocking the receptors, there is a restriction of the receptor's normal physiological function59. A different approach to regulate NMDAR receptors is thorough allosteric modulators that could allow cell type or circuit-specific modulation, due to widely distributed GluN2 expression, without global NMDAR overactivation59,65,122. In one study, we hypothesized that the compound CNS4 selectively modulates NMDA diheteromeric receptors (GluN2A, GluN2B, GuN2C, and GluN2C) based on (three) different glutamate concentrations. Electrophysiological recordings carried out on recombinant NMDA receptors expressed in xenopus oocytes revealed that 30μM and 100μM of CNS4 potentiated ionic currents for the GluN2C and GluN2D subunits with 0.3μM Glu/100μM Gly. However, when using 300μM Glu/100μM Gly, CNS4 inhibited the relative response in the GluN2D subunit and had no effect on the remaining subunits. CNS4 reduced the response to glutamate alone for GluN2A but increased it for GluN2B and did not appear to replace glutamate. Another set of electrophysiological recordings measuring current-voltage relationship was made in order to understand ion flow across the channel in the presence of CNS4. 100μM CNS4 numerically increased the ionic inward current through the channel pore with more positive membrane potential, reflected by a significant difference in reversal potential values, in the GluN2C and GluN2D subunits. CNS4 also exhibited a non-voltage dependent activity and it did not appear to compete with magnesium which naturally blocks the receptor. Finally, the effect of CNS4 on calcium uptake and cellular viability was study in neurons from primary rat brain culture. Cortial and striatal neurons were given excessive doses of synthetic agonist NMDA in order to hyperactivate native NMDAR. In the calcium assay, 100µM of CNS4 significantly increased calcium upatake when given with 300µM NMDA compared with NMDA alone in cortex and when given with 100µM and 300µM NMDA in striatum. In the MTS assay, CNS4 did not alter neuronal viability in either cortical or striatal neurons compared with NMDA alone. Also, when CNS4 was used in non treated neurons it did not alter neuronal viability. Findings from the primary brain culture let us conclude that CNS4 could facilitate calcium influx and possibly be non toxic for neurons.
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    Positive Modulatory Interactions of NMDA Receptor GluN1/2B Ligand Binding Domains Attenuate Antagonists Activity
    Bledsoe, Douglas N.; Tamer, Ceyhun; Mesic, Ivana; Madry, Christian; Klein, Bradley G.; Laube, Bodo; Costa, Blaise M. (Frontiers, 2017-05-09)
    N-methyl D-aspartate receptors (NMDAR) play crucial role in normal brain function and pathogenesis of neurodegenerative and psychiatric disorders. Functional tetra-heteromeric NMDAR contains two obligatory GluN1 subunits and two identical or different non-GluN1 subunits that include six different gene products; four GluN2 (A-D) and two GluN3 (A-B) subunits. The heterogeneity of subunit combination facilities the distinct function of NMDARs. All GluN subunits contain an extracellular N-terminal Domain (NTD) and ligand binding domain (LBD), transmembrane domain (TMD) and an intracellular C-terminal domain (CTD). Interaction between the GluN1 and co-assembling GluN2/3 subunits through the LBD has been proven crucial for defining receptor deactivation mechanisms that are unique for each combination of NMDAR. Modulating the LBD interactions has great therapeutic potential. In the present work, by amino acid point mutations and electrophysiology techniques, we have studied the role of LBD interactions in determining the effect of well-characterized pharmacological agents including agonists, competitive antagonists, and allosteric modulators. The results reveal that agonists (glycine and glutamate) potency was altered based on mutant amino acid sidechain chemistry and/or mutation site. Most antagonists inhibited mutant receptors with higher potency; interestingly, clinically used NMDAR channel blocker memantine was about three-fold more potent on mutated receptors (N521A, N521D, and K531A) than wild type receptors. These results provide novel insights on the clinical pharmacology of memantine, which is used for the treatment of mild to moderate Alzheimer's disease. In addition, these findings demonstrate the central role of LBD interactions that can be exploited to develop novel NMDAR based therapeutics.