Computer-aided discovery of debris disk candidates: A case study using the Wide-Field Infrared Survey Explorer (WISE) catalog

Homocysteine (Hcy) is thiol group containing the amino acid, which naturally occurs in all humans. Hcy is degraded in the body through two metabolic pathways, while a minor part is excreted through kidneys. The chemical reactions that are necessary for degradation of Hcy require the presence of the folic acid, vitamins B6 and B12. Consequently, the level of the total Hcy in the serum is influenced by the presence or absence of these vitamins. An elevated level of the Hcy, hyperhomocysteinemia (HHcy) and homocystinuria are connected with occlusive artery disease, especially in the brain, the heart, and the kidney, in addition to venous thrombosis, chronic renal failure, megaloblastic anemia, osteoporosis, depression, Alzheimer's disease, pregnancy problems, and others. Elevated Hcy levels are connected with various pathologies both in adult and child population. Causes of HHcy include genetic mutations and enzyme deficiencies in 5, 10-methylenetetrahydrofolate reductase (MTHFR) methionine synthase (MS), and cystathionine β-synthase(CβS). HHcy can be caused by deficiencies in the folate, vitamin B12 and to a lesser extent deficiency in the B6 vitamin what influences methionine metabolism. Additionally, HHcy can be caused by the rich diet and renal impairment. This review presents literature data from recent research related to Hcy metabolism and the etiology of the Hcy blood level disorder. In addition, we also described various pathological mechanisms induced by hereditary disturbances or nutritional influences and their association with HHcy induced pathology in adults and children and treatment of these metabolic disorders.

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Cell cycle re-entry mediated neurodegeneration and its treatment role in the pathogenesis of Alzheimer's disease

Lee

Casadesús

Zhu

et al. 2009

Neurochemistry International

116

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As one of the earliest pathologic changes, the aberrant re-expression of many cell cycle -related proteins and inappropriate cell cycle control in specific vulnerable neuronal populations in Alzheimer's disease (AD) is emerging as an important component in the pathogenesis leading to AD and other neurodegenerative diseases. These events are clearly representative of a true cell cycle, rather than epiphenomena of other processes since, in AD and other neurodegenerative diseases, there is a true mitotic alteration that leads to DNA replication. While the exact role of cell cycle reentry is unclear, recent studies using cell culture and animal models strongly support the notion that the dysregulation of cell cycle in neurons leads to the development of AD-related pathology such as hyperphosphorylation of tau and amyloid-β deposition and ultimately causes neuronal cell death. Importantly, cell cycle re-entry is also evident in mutant amyloid-β protein precursor and tau transgenic mice and, as in human disease, occurs prior to the development of the pathological hallmarks, neurofibrillary tangles and amyloid-β plaques. Therefore, the study of aberrant cell cycle regulation in model cellular and animal systems may provide extremely important insights into the pathogenesis of AD while serving as a means to test novel therapeutic approaches. KeywordsAlzheimer's disease; amyloid-β; cell cycle; neurodegeneration; tau phosphorylation CELL CYCLE ALTERATIONS IN ALZHEIMER'S DISEASE AND OTHER NEURODEGENERATIVE DISEASESPrimary neurons in the normal brain are viewed as being quiescent and in G 0 (Obrenovich et al., 2005). However, in Alzheimer's disease (AD), multiple lines of evidence suggest that neurons vulnerable to degeneration emerge from this postmitotic state -phenotypically suggestive of cells that are cycling, rather than the normal terminally differentiated nondividing state (Arendt et al

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Glutathione “Redox Homeostasis” and Its Relation to Cardiovascular Disease

Bajić

Neste

Obradović

et al. 2019

Oxidative Medicine and Cellular Longevity

101

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More people die from cardiovascular diseases (CVD) than from any other cause. Cardiovascular complications are thought to arise from enhanced levels of free radicals causing impaired “redox homeostasis,” which represents the interplay between oxidative stress (OS) and reductive stress (RS). In this review, we compile several experimental research findings that show sustained shifts towards OS will alter the homeostatic redox mechanism to cause cardiovascular complications, as well as findings that show a prolonged antioxidant state or RS can similarly lead to such cardiovascular complications. This experimental evidence is specifically focused on the role of glutathione, the most abundant antioxidant in the heart, in a redox homeostatic mechanism that has been shifted towards OS or RS. This may lead to impairment of cellular signaling mechanisms and elevated pools of proteotoxicity associated with cardiac dysfunction.

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Evidence for the progression through S-phase in the ectopic cell cycle re-entry of neurons in Alzheimer disease

Bonda

Evans²,

Santocanale³

et al. 2009

Aging

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Aberrant neuronal re-entry into the cell cycle is emerging as a potential pathological mechanism in Alzheimer disease (AD). However, while cyclins, cyclin dependent kinases (CDKs), and other mitotic factors are ectopically expressed in neurons, many of these proteins are also involved in other pathological and physiological processes, generating continued debate on whether such markers are truly indicative of a bona fide cell cycle process. To address this issue, here we analyzed one of the minichromosome maintenance (Mcm) proteins that plays a role in DNA replication and becomes phosphorylated by the S-phase promoting CDKs and Cdc7 during DNA synthesis. We found phosphorylated Mcm2 (pMcm2) markedly associated with neurofibrillary tangles, neuropil threads, and dystrophic neurites in AD but not in aged-matched controls. These data not only provide further evidence for cell cycle aberrations in AD, but the cytoplasmic, rather than nuclear, localization of pMcm2 suggests an abnormal cellular distribution of this important replication factor in AD that may explain resultant cell cycle stasis and consequent neuronal degeneration.

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Cell Cycle Deregulation in the Neurons of Alzheimer’s Disease

Moh

Kubiak

Bajić³

et al. 2011

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The cell cycle consists of four main phases: G1, S, G2, and M. Most cells undergo these cycles up to 40–60 times in their life. However, neurons remain in a nondividing, nonreplicating phase, G0. Neurons initiate but do not complete cell division, eventually entering apoptosis. Research has suggested that like cancer, Alzheimer’s disease (AD) involves dysfunction in neuronal cell cycle reentry, leading to the development of the two-hit hypothesis of AD. The first hit is abnormal cell cycle reentry, which typically results in neuronal apoptosis and prevention of AD. However, with the second hit of chronic oxidative damage preventing apoptosis, neurons gain “immortality” analogous to tumor cells. Once both of these hits are activated, AD can develop and produce senile plaques and neurofibrillary tangles throughout brain tissue. In this review, we propose a mechanism for neuronal cell cycle reentry and the development of AD.

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Review: Cell cycle aberrations and neurodegeneration

Bonda¹,

Bajić²,

Spremo-Potparević

et al. 2010

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The cell cycle is a highly regulated and fundamental cellular process that involves complex feedback regulation of many proteins, and any compromise to its integrity elicits dire consequences for the cell. For example, in neurodegenerative diseases such as Alzheimer disease (AD), evidence for abnormal cell cycle re-entry precedes other hallmarks of disease and as such, implicates cell cycle aberrations in the aetiology of AD. The mechanism(s) for cell cycle re-entry in AD, however, remain unclear. Current theory suggests it to be part of a combination of early events that together elicit the degenerative pathology and cognitive phenotype consistent with the disease. We propose a ‘Two-Hit Hypothesis’ that highlights the concerted interaction between cell cycle alterations and oxidative stress that combine to produce neurodegeneration. Here, we review the evidence implicating cell cycle mechanisms in AD and how such changes, especially in combination with oxidative stress, would lead to a cascade of events leading to disease. Based on this concept, we propose new opportunities for disease treatment.

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Analysis of premature centromere division (PCD) of the X chromosome in Alzheimer patients through the cell cycle

Spremo-Potparević¹,

Živković²,

Djelić

et al. 2004

Experimental Gerontology

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Cohesion and the aneuploid phenotype in Alzheimer's disease: A tale of genome instability

Bajić

Spremo-Potparević

Živković

et al. 2015

Neuroscience & Biobehavioral Reviews

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Vladan Bajić

Homocysteine and Hyperhomocysteinaemia

Cell cycle re-entry mediated neurodegeneration and its treatment role in the pathogenesis of Alzheimer's disease

Glutathione “Redox Homeostasis” and Its Relation to Cardiovascular Disease

Evidence for the progression through S-phase in the ectopic cell cycle re-entry of neurons in Alzheimer disease

Cell Cycle Deregulation in the Neurons of Alzheimer’s Disease

Review: Cell cycle aberrations and neurodegeneration

Analysis of premature centromere division (PCD) of the X chromosome in Alzheimer patients through the cell cycle

Cohesion and the aneuploid phenotype in Alzheimer's disease: A tale of genome instability

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