Effect of Calebin-A on Critical Genes Related to NAFLD: A Protein-Protein Interaction Network and Molecular Docking Study.

Background: Calebin-A is a minor phytoconstituent of turmeric known for its activity against inflammation, oxidative stress, cancerous, and metabolic disorders like Non-alcoholic fatty liver disease(NAFLD). Based on bioinformatic tools. Subsequently, the details of the interaction of critical proteins with Calebin-A were investigated using the molecular docking technique. Methods: We first probed the intersection of genes/ proteins between NAFLD and Calebin-A through online databases. Besides, we performed an enrichment analysis using the ClueGO plugin to investigate signaling pathways and gene ontology. Next, we evaluate the possible interaction of Calebin-A with significant hub proteins involved in NAFLD through a molecular docking study. Results: We identified 87 intersection genes Calebin-A targets associated with NAFLD. PPI network analysis introduced 10 hub genes (TP53, TNF, STAT3, HSP90AA1, PTGS2, HDAC6, ABCB1, CCT2, NR1I2, and GUSB). In KEGG enrichment, most were associated with Sphingolipid, vascular endothelial growth factor A (VEGFA), C-type lectin receptor, and mitogen-activated protein kinase (MAPK) signaling pathways. The biological processes described in 87 intersection genes are mostly concerned with regulating the apoptotic process, cytokine production, and intracellular signal transduction. Molecular docking results also directed that Calebin-A had a high affinity to bind hub proteins linked to NAFLD. Conclusion: Here, we showed that Calebin-A, through its effect on several critical genes/ proteins and pathways, might repress the progression of NAFLD.

How does the Immunological System Change during the SARS-COV-2 Attack? A Clue for the New Immunotherapy Discovery.

The COVID-19 pandemic caused by the Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-COV-2) is one of the biggest unsolved global problems of the 21st century for which there has been no definitive cure yet. Like other respiratory viruses, SARS-COV-2 triggers the host immunity dramatically, causing dysfunction in the immune system, both innate and adaptive, which is a common feature of COVID-19 patients. Evidence shows that in the early stages of COVID-19, the immune system is suppressed while it is overactive in severe patients characterized by excessive and prolonged inflammatory responses called "Cytokine Storm". There are many elements in the immune system that undergo alterations as the disease progresses. Some significant changes in the innate immune system following infection with SARS-COV-2 include delayed or inhibited interferon type 1 production by the infected cells leading to elevated virus replication, excessive recruitment of activated monocytes and macrophages, decrease in eosinophil population (eosinopenia), consequent decrease in CD8+T lymphocyte proliferation, natural killer (NK) cell dysfunction, and increase in neutrophil infiltration (neutrophilia) and neutrophil extracellular trap (NET) formation. Moreover, hallmark alterations in the adaptive immune system in this process cause an overall decrease in the T lymphocyte number (lymphopenia) and changes in the activity of some lymphocyte subsets and a number of B cells. This review delves into the mentioned changes in the immune system following SARS-COV-2 infection and the implications thereof to guide the development of immunotherapies for patients with COVID-19.

A highly sensitive fluorescent aptasensor for detection of prostate specific antigen based on the integration of a DNA structure and CRISPR-Cas12a.

Herein, a facile fluorescent CRISPR-Cas12a-based sensing strategy is presented for prostate specific antigen (PSA), as a prostate cancer biomarker, with the assistance of a cruciform DNA nanostructure and PicoGreen (PG) as a fluorochrome. Highly sensitive recognition of PSA is one of the virtues of the proposed method which comes from the use of unique features of both CRISPR-Cas12a and DNA structure in the design of the aptasensor. The presence of PSA creates a cruciform DNA nanostructure in the sample which can be loaded by PG and make sharp fluorescence emission. While, when there is no PSA, the CRISPR-Cas12a digests sequences 1 and 3 as single-stranded DNAs, causing no DNA structure and a negligible fluorescence is detected after addition of PG. This aptasensor presents a sensitive recognition performance with detection limit of 4 pg/mL and a practical use for determination of PSA in serum samples. So, this analytical strategy introduces a convenient and highly sensitive approach for detection of disease biomarkers.

Natural products as safeguards against monosodium glutamate-induced toxicity.

Monosodium glutamate is a sodium salt of a nonessential amino acid, L-glutamic acid, which is widely used in food industry. Glutamate plays an important role in principal brain functions including formation and stabilization of synapses, memory, cognition, learning, as well as cellular metabolism. However, ingestion of foodstuffs rich in monosodium glutamate can result in the outbreak of several health disorders such as neurotoxicity, hepatotoxicity, obesity and diabetes. The usage of medicinal plants and their natural products as a therapy against MSG used in food industry has been suggested to be protective. Calendula officinalis, Curcuma longa, Green Tea, Ginkgo biloba and vitamins are some of the main natural products with protective effect against mentioned monosodium glutamate toxicity through different mechanisms. This review provides a summary on the toxicity of monosodium glutamate and the protective effects of natural products against monosodium glutamate -induced toxicity.