School Of Basic And Applied Sciences

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    Evaluation of amyloid beta (aβ)-induced Mitochondrial dysfunction: Neuroprotective role of Apurinic/apyrimidinic endonuclease (ape1) Via its interaction with cysteamine Dioxygenase (ado)
    (Central University of Punjab, 2020) Kaur,Navrattan; Mantha, Anil K.
    Oxidative stress and damage to mitochondrial DNA during the aging process can impair mitochondrial energy metabolism and ion homeostasis in neurons, ultimately leading to neurodegeneration. Themain pathway for repairing oxidative base lesions is base excision repair (BER), and such repair is crucial for neurons owing to high rate of oxygen metabolism. Apurinic/apyrimidinic endonuclease (APE1) is a protein of this pathway involved in DNA repair and also in the redox co-activating function of different transcription factors. Thus, manipulation of DNA repair mechanisms can be thought of as a putative approach to prevent neuronal loss in neurodegenerative disorders like Alzheimer’s disease (AD). Ginkgo biloba has been studied as a possible treatment for dementia and AD. The ginkgolides present in G. biloba possess antioxidant, neuroprotective and cholinergic activities. The aim of the study was to explore the repair and redox functions of APE1 and a detailed mechanism of association of APE1 with ADO (a thiol dioxygenase) and functional cross-talk between them has been studied. In the present study, we have standardized the differentiation of SH-SY5Y neuroblastoma cells into the cells possessing a mature neuron-like phenotype. The results of cell viability assay showed that differentiated cells are more sensitive/vulnerable to oxidative stress, which is elicited by Aβ. H2DCFDA and DAF- FM-based detection of ROS and RNS strongly advocates that under oxidative stress conditions elicited by Aβ, GB exerts ameliorating effect to render neuroprotection to the SH-SY5Y cells due to its antioxidant nature. Significant decrease in nNOS expression was seen, when cells were pre-treated with GB and then given Aβ treatment in whole cell, cytosol and nucleus. This shows that GB pre-treatment decreases the RNS (NO) levels due to its anti-oxidant property. Determination of DNA damage in terms of measurement of 8-oxo-dG was seen to be more pronounced in mitochondria. In response to DNA damage, pre-treatment with GB decreased the expression of DNA repair enzyme APE1 expression in mitochondria, showing that GB aids in lowering the oxidative stress generated by Aβ in the mitochondria. In the nuclear extracts, upon treatment with GB, there was a significant increase in ADO expression and Aβ treatment also increased the expression of ADO. Whereas, combination treatment of Aβ and GB led to lower expression of ADO. This points towards the possibility that ADO might be translocating to nucleus under oxidative stress and GB might be affecting APE1 – ADO interaction in lowering oxidative stress by the anti-oxidant action of GB, which was clearly observed by immunostaining using confocal microscopy. JC-1 assay points toward GB’s role in restoring the mitochondrial membrane potential against Aβ- challenge. Determination of apoptotic markers (Caspase 9 and AIF) showed that Aβ(25-35) induced oxidative stress caused initiation of apoptosis and GB treatment was able to rescue apoptosis. Our study elucidates activation of synaptic CaMKII and CREB exerting neuroprotective effects; and GB acting to restore the expression and active, phosphorylated state of CaMKII and CREB in presence of Aβ-induced oxidative stress in the SH-SY5Y neuroblastoma cells. This study points towards the use of phytochemicals like GB which will may prove to be beneficial for the enhancement of synaptic functionality and promote neuroprotection.
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    OXIDATIVE STRESS INDUCED CELL PROLIFERATION AND DNA REPAIR MECHANISMS IN GLIOBLASTOMA CELLS: ROLE OF ENPP2 AND APE1
    (Central University of Punjab, 2018) Cholia, Ravi Parkash; Mantha, Anil K. and Kumar, Raj
    Glioblastoma Multiforme (GBM) is a grade IV, most frequent, and invasive devastating brain tumor with poor prognosis, even with the advancement of multimodal therapies, patients have survival period of less than 15 months. GBM is a multifactorial disease with oxidative stress as a key accelerating player. In the present study, rat glioma C6 and human glioblastoma U-87 MG cell lines were exposed to non-cytotoxic concentrations i.e. 10 -35) peptide, 10 U/ml GO, and 50 M H2O2, respectively. Further, the ROS levels were measured via NBT and H2DCFDA assays. Our genome encounters exogenous and intracellular oxidants which result in the DNA damage; small DNA base lesions such as apurinic/apyrimidinic (AP) sites are generated following the oxidants exposure and repairing of these AP sites is the prerequisite to maintaining the genomic integrity. In the present study, it was observed that APE1 being a redox-sensitive protein, with the moderate level of oxidative stress [induced -35) peptide, GO, and H2O2] resulted in the elevation of APE1 expression as measured using Western blotting, RT-PCR, and (repair) activity was boosted after the treatment of oxidants. Oxidative stress also resulted in the secretion of APE1 extracellularly. Additionally, in this study dysregulated expression of BER-pathway enzymes were observed after the treatment of non-cytotoxic concentrations of the oxidants. Cancer shows higher metabolic properties as compared to the normal cells. Pyruvate Kinase M2 (PKM2) one of the isoform of pyruvate kinase (PK), is a key enzyme in the glycolytic pathway, which catalyses the terminal step of the glycolysis, converts phosphoenolpyruvate (PEP) into pyruvate. PKM2 also perform nonglycolytic functions via enhancing the expression of cyclin D, c-myc, and contributing towards the aggressiveness of GBM. In the present study, oxidative stress resulted in up-regulation of PKM2 level, as analyzed using Western blotting and majorly in the cytosolic regions as identified by immunocytochemistry. Ectonucleotide pyrophosphatase/phosphordiestrase2 (ENPP2) is the secretary protein, known to be involved in a variety of processes like embryonic development, blood vessel formation during development, inflammation, favoring PKM2 dimeric form, and progression of cancer through its enzymatic product LPA. ENPP2 is highly expressed in the GBM, and LPA receptors are also predominate in GBM and play a role in its growth and development. In the present study, elevated expression and activity of ENPP2 was observed after the treatment of non-cytotoxic doses of oxidants in C6 and U-87 MG cells as analyzed using Western blotting and immunocytochemistry. In addition, LPA treatment resulted in the induction of migratory potential of C6 and U-87 MG cells. LPA treatment also up-regulated the key transcription factors such as c-jun, p-c-jun, NF- B, and HIF-1- advocating for their involvement in the survival of GBM cells. LPA treatment resulted in the timedependent increase in the PKM2 and ENPP2 expression and subcellular translocation in the C6 and U-87 MG cells. However, LPA treatment resulted in the elevation of nuclear APE1 expression after 48 hr incubation period. Oxidants - 35) peptide, GO, and H2O2 treatment enhanced the secretory levels of ENPP2 in the extracellular media up to 48 hr, suggesting the protective role of ENPP2 against the oxidative stress. Co-localization of APE1, PKM2, and ENPP2 were observed in the C6 and U87 MG cells when treated with -35) peptide, GO, and H2O2 treatment suggesting the role of oxidative stress in the cross talk interaction of three proteins towards the aggressiveness of GBM. In addition, anti-APE1 inhibitors were synthesized activity, and one of the screened molecule GR5G-b showed ani-proliferative property along with dysregulated APE1 level and repair function; and also displayed potential in cell cycle arrest as analyzed by flow cytometry. Taken together, it can be concluded that oxidative stress enhances the aggressiveness of GBM cells via up-regulating the key proteins (APE1, PKM2, and ENPP2) and altering the functions associated as studied in C6 and U-87 MG cell lines. Further studies focusing towards blocking of their activities by designing, help in development of new therapeutic interventions for GBM.
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    Phytochemical ginkgolide b protects cultured neuroblastoma SH-SY5Y cells against a?(25-35) induced oxidative stress responses by maintaining the mitochondrial integrity
    (Rasayan Journal of Chemistry, c/o Dr. Pratima Sharma, 2020) Kaur, N; Kaur, S; Saini, M; Dhiman, M; Mantha, A.K.
    Alzheimer�s disease is associated with oxidative stress induced by accumulation of A? peptide, by disrupting the mitochondrial function. In this study, the oxidative stress responses induced by A?(25-35) and protective effects of diterpenoid phytochemical Ginkgolide B (GB) were evaluated by the determination of cellular oxidant/antioxidant status, oxidative DNA base damage and repair capacity of cells through evaluation of mitochondrial BER pathway status and the multifunctional enzyme APE1 in human neuroblastoma SH-SY5Y cells, and evaluation of mitochondrial membrane potential and changes in apoptotic pathway. It was found that A?(25-35) treatment increased ROS/RNS production, increased the activities of antioxidant SOD and Catalase enzymes, decreased the expression of mitochondrial SOD (SOD2), induced oxidative DNA base damage, might be altered the repair capacity as analyzed by the transcriptional and translational expression of APE1 and other BER pathway enzymes in the mitochondria, disrupted the mitochondrial membrane potential and induced apoptosis as a result of these responses. Phytochemical modulation by the pre-treatment of GB for 3 hr followed by the treatment of A?(25-35) for a period of 24 hr caused decrease in ROS/RNS, increase in activities of antioxidant enzymes and expression of SOD2, decreased oxidative DNA base damage and increased transcriptional and translational expression of APE1, increased/restored expression of APE1 and polymerase gamma (?) in the mitochondria, restored mitochondrial membrane potential and rescued the SH-SY5Y cells from mitochondrial-mediated apoptosis against A?(25-35) induced oxidative stress responses. Taken together, GB showed neuroprotection by restoring cellular antioxidant defense system, repair capacity of cells and restoring mitochondrial integrity (genome and membrane potential), thus rescuing the SH-SY5Y cells from A?(25-35) induced oxidative stress responses. � RAS?YAN. All rights reserved.