Pravir Kumar

The Insulin/Akt Signaling Pathway Is Targeted by Intracellular β-Amyloid

Intraneuronal beta-amyloid (Abeta(i)) accumulates early in Alzheimers disease (AD) and inclusion body myositis. Several organelles, receptor molecules, homeostatic processes, and signal transduction components have been identified as sensitive to Abeta. Although prior studies implicate the insulin-PI3K-Akt signaling cascade, a specific step within this or any essential metabolic or survival pathway has not emerged as a molecular target. We tested the effect of Abeta42 on each component of this cascade. In AD brain, the association between PDK and Akt, phospho-Akt levels and its activity were all decreased relative to control. In cell culture, Abeta(i) expression inhibited both insulin-induced Akt phosphorylation and activity. In vitro experiments identified that beta-amyloid (Abeta), especially oligomer preparations, specifically interrupted the PDK-dependent activation of Akt. Abeta(i) also blocked the association between PDK and Akt in cell-based and in vitro experiments. Importantly, Abeta did not interrupt Akt or PI3K activities (once stimulated) nor did it affect more proximal signal events. These results offer a novel therapeutic strategy to neutralize Abeta-induced energy failure and neuronal death.

Differential Effects of Mitochondrial Heat Shock Protein 60 and Related Molecular Chaperones to Prevent Intracellular β-Amyloid-induced Inhibition of Complex IV and Limit Apoptosis

Defects in mitochondrial oxidative metabolism, in particular decreased activity of cytochrome c oxidase, have been reported in Alzheimer disease tissue and in cultured cells that overexpress amyloid precursor protein. Mitochondrial dysfunction contributes to neurodegeneration in Alzheimer disease partly through formation of reactive oxygen species and the release of sequestered molecules that initiate programmed cell death pathways. The heat shock proteins (HSP) are cytoprotective against a number of stressors, including accumulations of misfolded proteins and reactive oxygen species. We reported on the property of Hsp70 to protect cultured neurons from cell death caused by intraneuronal β-amyloid. Here we demonstrate that Hsp60, Hsp70, and Hsp90 both alone and in combination provide differential protection against intracellular β-amyloid stress through the maintenance of mitochondrial oxidative phosphorylation and functionality of tricarboxylic acid cycle enzymes. Notably, β-amyloid was found to selectively inhibit complex IV activity, an effect selectively neutralized by Hsp60. The combined effect of HSPs was to reduce the free radical burden, preserve ATP generation, decrease cytochrome c release, and prevent caspase-9 activation, all important mediators of β-amyloid-induced neuronal dysfunction and death.

Parkin Reverses Intracellular β-Amyloid Accumulation and Its Negative Effects on Proteasome Function

The significance of intracellular β‐amyloid (Aβ42) accumulation is increasingly recognized in Alzheimers disease (AD) pathogenesis. Aβ removal mechanisms that have attracted attention include IDE/neprilysin degradation and antibody‐mediated uptake by immune cells. However, the role of the ubiquitin‐proteasome system (UPS) in the disposal of cellular Aβ has not been fully explored. The E3 ubiquitin ligase Parkin targets several proteins for UPS degradation, and Parkin mutations are the major cause of autosomal recessive Parkinsons disease. We tested whether Parkin has cross‐function to target misfolded proteins in AD for proteasome‐dependent clearance in SH‐SY5Y and primary neuronal cells. Wild‐type Parkin greatly decreased steady‐state levels of intracellular Aβ42, an action abrogated by proteasome inhibitors. Intracellular Aβ42 accumulation decreased cell viability and proteasome activity. Accordingly, Parkin reversed both effects. Changes in mitochondrial ATP production from Aβ or Parkin did not account for their effects on the proteasome. Parkin knock‐down led to accumulation of Aβ. In AD brain, Parkin was found to interact with Aβ and its levels were reduced. Thus, Parkin is cytoprotective, partially by increasing the removal of cellular Aβ through a proteasome‐dependent pathway.

Cross-functional E3 ligases Parkin and C-terminus Hsp70-interacting protein in neurodegenerative disorders

J. Neurochem. (2012) 120, 350–370.

Rotenone-induced parkinsonism elicits behavioral impairments and differential expression of parkin, heat shock proteins and caspases in the rat.

Rotenone is a pesticide that inhibits mitochondrial complex I activity, thus creating an environment of oxidative stress in the cell. Many studies have employed rotenone to generate an experimental animal model of Parkinsons disease (PD) that mimics and elicits PD-like symptoms, such as motor and cognitive decline. Cytoprotective proteins including parkin and heat shock proteins (HSPs) play major roles in slowing PD progression. Moreover, evidence suggests that mitochondrial dysfunction and oxidative stress-dependent apoptotic pathways contribute to dopaminergic neuron degeneration in PD. Here, rats were chronically exposed to rotenone to confirm that it causes a debilitating phenotype and various behavioral defects. We also performed histopathological examinations of nigrostriatal, cortical and cerebellar regions of rotenone-treated brain to elucidate a plausible neurodegenerative mechanism. The results of silver, tyrosine hydroxylase (TH), parkin, ubiquitin and caspase staining of brain tissue sections further validated our findings. The stress response is known to trigger HSP in response to pharmacological insult. These protective proteins help maintain cellular homeostasis and may be capable of rescuing cells from death. Therefore, we assessed the levels of different HSPs in the rotenone-treated animals. Collectively, our studies indicated the following findings in the striatum and substantia nigra following chronic rotenone exposure in an experimental PD model: (i) behavioral deficit that correlated with histopathological changes and down regulation of TH signaling, (ii) decreased levels of the cytoprotective proteins parkin, DJ1 and Hsp70 and robust expression of mitochondrial chaperone Hsp60 according to Western blot, (iii) increased immunoreactivity for caspase 9, caspase 3 and ubiquitin and decreased parkin immunoreactivity.

Nanoparticle mediated targeting of VEGFR and cancer stem cells for cancer therapy

Angiogenesis is a crucial process in tumor pathogenesis as it sustains malignant cells with nutrients and oxygen. It is well known that tumor cells secrete various growth factors, including VEGF, which triggers endothelial cells to form new capillaries. Prevention of expansion of new blood vessel networks results in reduced tumor size and metastasis. Production of VEGF is driven by hypoxia via transcriptional activation of the VEGF gene by HIF-1α.Tumours are now understood to contain different types of cells, and it is the cancer stem cells that retain the ability to drive the tumours growth. They are called cancer stem cells because, like stem cells present in normal tissues of the body, they can self-renew and differentiate. These cancer stem cells are responsible for the relapse of cancer as they are found to be resistant to conventional modes of cancer therapy like chemotherapy and radiation.In this review, a novel mode of treatment of cancer is proposed, which utilizes the twin nanoparticle to target endothelial cells in the niche of cancer stem cell. The nanoparticle discussed in this review, is a twin nanoparticle of iron coated with gold, which targets VEGF positive cell in the vicinity of cancer stem cell. In the twin nanoparticle, one particle will recognize cancer stem cell, and another conjugated nanoparticle will recognize VEGF positive cells, thereby inhibiting endothelial cells in the proximity of cancer stem cell. This novel strategy will inhibit angiogenesis near cancer stem cell hence new tumour cannot grow and old tumour will be unable to metastasize.

Transgenic expression of β-APP in fast-twitch skeletal muscle leads to calcium dyshomeostasis and IBM-like pathology

Intracellular deposition of the β‐amyloid (Aβ) peptide is an increasingly recognized pathological hallmark associated with neurodegeneration and muscle wasting in Alzheimers disease (AD) and inclusion body myositis (IBM), respectively. Previous reports have implicated dysregulation of β‐amyloid precursor protein (αAPP) expression in IBM. Accumulation of full‐length αAPP, its various proteolytic derivatives including A, and phospho‐tau into vacuolated inclusions is an early pathogenic event. We previously reported on a statistical tendency favoring fast twitch fiber involvement in IBM, reminiscent of the tissue specific patterns of misfolded protein deposition seen in neurodegenerative diseases. To test this principle, we generated an animal model in which human wild‐type (WT) βAPP expression was limited to postnatal type II skeletal muscle. Hemizygous transgenic mice harboring increased levels of holoβAPP751 and Aβ in skeletal muscle fibers became significantly weaker with age compared with nontransgenic littermates and exhibited typical myopathic features. A subpopulation of dissociated muscle fibers from transgenic mice exhibited a 2‐fold increase in resting calcium and membrane depolarization compared with nontransgenic littermates. Taken together, these data indicate that overexpression of human βAPP in fast twitch skeletal muscle of transgenic mice is sufficient for the development of some features characteristic of IBM, including abnormal tau histochemistry. The increase in resting calcium and depolarization are novel findings, suggesting both a mechanism for the weakness and an avenue for therapeutic intervention in IBM.—Moussa, C. E‐H., Fu, Q., Kumar, P., Shtifman, A., Lopez, J. R., Allen, P. D., LaFerla, F., Weinberg, D., Magrane, J., Aprahamian, T., Walsh, K., Rosen, K. M., Querfurth, H. W. Transgenic expression of ‐APP in fast‐twitch skeletal muscle leads to calcium dyshomeostasis and IBM‐like pathology. FASEB J. 20, E1570 –E1578 (2006)

Tau Phosphorylation, Molecular Chaperones, and Ubiquitin E3 Ligase: Clinical Relevance in Alzheimer's Disease

Alzheimers disease (AD) is characterized by dementia, cognitive disabilities, and tauopathy. Tau is a microtubule associated protein that helps maintain the neuronal network. While phosphorylation of tau protein causes disruption of the microtubular network, dephosphorylation allows reconstitution of the microtubule network. Several kinases, e.g., MARK, MAPK, and protein kinase C, are known to hyperphosphorylate tau, leading to disruption of the microtubular network and formation of neurofibrillary tangles (NFTs), which are further glycosylated, glycated, and have lipid peroxide adducts that impair the neuronal transport system and affect memory formation and retention. Moreover, intracerebral administration of amyloid-β oligomers causes hyperphosphorylation of tau, but whether it is involved in the formation of NFTs is still unclear. Further, amyloid burden activates AMP-activated protein kinase that increases phosphorylation of tau at position Ser262/Ser356 and Ser396. Several phosphatases are present at low levels in AD brains indicating that their down regulation results in abnormal hyperphosphorylation of tau. However, evidence strengthens a possible link between tau phosphorylation and molecular chaperone mediated tau metabolism for the clearance of toxic tau accumulation and has a crucial role in tauopathy. Furthermore, accumulation of phosphorylated tau protein and the possibility of removing the toxic phosphorylated tau protein from the milieu indicates that the chaperone interacts with phosphorylated tau and promotes its degradation. For instance, Hsp90 and cdc37 regulate tau stability and phosphorylation dynamics whereas Hsp27 is able to modulate neuronal plasticity, while 14-3-3 is involved in the interaction of tau with small HSPs. Hsp70 ATPase acts as a modulator in AD therapeutics while Hsc70 rapidly engages tau after microtubular destabilization. Herein, we highlight the various causes of tauopathy and HSP-E3 ligase mediated therapeutics in AD.

Sesamol and naringenin reverse the effect of rotenone-induced PD rat model.

In the previous report (Sonia Angeline et al., 2012), we showed an altered expression of protective proteins in rotenone-induced Parkinsons disease (PD)-like rat model. This model exhibited a marked attenuation in the expression of parkin, C terminus Hsp70 interacting protein (CHIP) and PARK 7 protein (DJ1) while enhanced levels of caspases and ubiquitin were seen. Herein, we confirmed the neuroprotective role of sesamol and naringenin individually on rotenone-induced rodent model of PD. Rotenone administration was given for 11days to generate the PD model (Sonia Angeline et al., 2012). From 11th day onward individual doses of sesamol (15mg/kg) and naringenin (10mg/kg) drugs were given orally to the rotenone PD rat model for 10 consecutive days. The impact of drugs markedly improved the motor skills, body weight, expression of parkin, DJ1, tyrosine hydroxylase and CHIP compared to the group treated with rotenone alone in the striatum and substantia nigra. These results were correlated with the reduction in caspase and ubiquitin levels by immunostaining and immunoblotting. Moreover, improved morphology and survivability of neurons were seen upon sesamol and naringenin treatment in the same rat PD model. Further we confirmed the efficacy of neuroprotective biomolecule administration on muscle from the above PD model and observed the restoration in muscle morphology, elevated level of parkin, DJ1, differential expression of heat shock proteins and reduced cell death. To conclude, for the first time we are demonstrating the comprehensive role of sesamol and naringenin (rotenone-induced PD model) in neuro and myoprotection that would have great clinical significance.

Naringenin and quercetin reverse the effect of hypobaric hypoxia and elicit neuroprotective response in the murine model

Exposure to high-altitude results in hypobaric hypoxia which is considered as an acute physiological stress. This condition often leads to high-altitude illnesses such as high-altitude cerebral edema, high altitude pulmonary edema and hypoxic muscle weakness. Hypoxic injuries can be prevented by either preconditioning with cobalt chloride or treatment with drugs. The aim of current investigation was to evaluate the effect of naringenin (NGEN) and quercetin (QUR) against behavioral impairment and neuronal damage in hypoxia induced murine model. An oral administration of NGEN or QUR (10mg/kg each) was given to the animal prior to every hypoxic treatment. Behavioral changes were evaluated along with the hypoxia exposure for all the groups. After hypoxia exposure and drug administration, the mice were euthanized; brains were harvested and stored for further analysis. Expressions of hypoxia induced proteins were ensured by Western blotting. Our results demonstrate expression of hypoxia inducible factor 1α (HIF1α), vascular endothelial growth factor (VEGF), active caspase 3 and ubiquitin levels were significantly reduced upon drug treatment. However, expressions of chaperones (Hsp70, Hsp90 and C-terminus Hsp70 interacting protein) were moderately changed. We established our findings based on behavioral test, hematoxylin and eosin as well as amino-cupric silver stainings. In addition, the protective nature of these drugs was corroborated with immunoblot and immunofluorescence results, where we confirmed the down regulation of caspase 3 and ubiquitinated proteins. To conclude, treatment with NGEN and QUR alone substantially ameliorated hypoxia induced brain dysfunction and acts like a neuroprotectant.