COVID-19 pneumonia seems to be a lung injury caused by the hyperactivation immune effector cells. High-dose vitamin C may result in immunosuppression at the level of these effectors. Therefore, intravenous high-dose vitamin C could be safe and beneficial choice of treatment in the early stages of COVID-19.
Acquired disturbances of several aspects of cellular metabolism appear pathologically important in sporadic Alzheimer's disease (SAD). Among these, brain glucose utilization is reduced in the early stages of the disease. Hyperinsulinemia, which is a characteristic finding of insulin resistance, results in a central insulin deficit. Insufficient insulin signaling impairs the intricate balance of nitric oxide regulation of the central nervous system. Reduction in central insulin decreases neuronal nitric oxide synthase and increases inducible synthase activity. This, in turn, decreases astrocytic energy substrates and antioxidant supply of neurons. In addition, an increase in peroxynitrite formation impairs redox balance. Hyperleptinemia and glucose excess, which are the other parameters of insulin resistance, may worsen the reduced astrocytic energy supply and the ongoing inflammation via the inhibition of AMP-activated protein kinase (AMPK). Consequently, energy deficit and inflammation in neuronal tissue may cause neurodegeneration of SAD.
Several protective cellular mechanisms protect against the accumulation of reactive oxygen species (ROS) and the concomitant oxidative stress. Therefore, any reduction in glucose or fatty acid flux into cells leading to a decrease in the production of reducing equivalents would also lead to a decreased ROS production and protect cells against oxidative stress. In the presence of insulin, FOXO proteins are localized from the nucleus to the cytoplasm and degraded. An increase in cellular glucose uptake will lead to increased production of ROS. This in turn activates the stress-responsive Jun-N-terminal kinase (JNK), which promotes nuclear translocation of FOXO proteins, upregulating some important target genes including stress resistance. Consequently, insulin resistance should result in decreased cellular ROS production. For this reason, insulin resistance could be a physiological mechanism activated at the cellular level in response to conditions stimulating ROS production and leading to the prevention of oxidative stress, and extension of life. Concerning the whole organism, however, IR is a maladaptive process in the long term causing a diabetic state.
Damaged DNA can lead to aneuploidy and/or chromosomal instability, which is believed to be major contributor to tumor progression. DNA damage in response to genotoxic and oncogenic stresses activate the tumor suppressor pathways initiating DNA damage response (DDR). One of the cellular fates in response to DDR is permanent growth arrest in mitotically active cells, including stem cells, leading to senescence. On the other hand, DDR reasons in adaptive changes in postmitotic cells. These cellular alterations happen through complex interactions and function to disrupt the existing cellular homeostasis. Significant metabolic changes occurred by the influence of the major tumor suppressor protein p53 and other related factors such as FOXO, AMPK, PARP, NF-kappaB and PGC-1 are discussed in the article. After a strong correlation established between the systemic DNA damage response to inhibit ongoing malignant transformation and metabolic syndrome characteristics, logical extrapolations for type 2 diabetes, cardiovascular disease, and aging are carried out. Finally, therapeutic evaluations are performed in the light of the novel pathophysiological data implying that "metabolic syndrome" is a real disease.
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