Background:
Histone deacetylase (HDAC) inhibition has been found to be effective in the treatment of
inflammatory bowel disease. Previous studies reported that Cinnamyl sulfonamide hydroxamate derivatives possessed nonselective HDAC inhibition.
Objective:
The present study was designed to screen three selected Cinnamyl sulfonamide hydroxamate derivatives, NMJ1, NMJ-2 and NMJ3 for in vitro anti-inflammatory response by assessing the expression of pNF-κB in lipopolysaccharide
(LPS)-induced inflammatory changes on RAW 264.7 cells and in vivo anti-inflammatory response in acetic acid (AA) and
2.4-dinitrochlorobenzene (DNCB)-induced colitis models in Wistar rats.
Method:
AA-induced colitis was produced in Wistar rats by intra-colonic administration of 1 ml AA. DNCB-induced colitis
was produced by spraying 250 µL DNCB in acetone (20g/L) on the nape of the rats for 14 days followed by the intracolonic
administration on day 15. Drugs were administered for three days after the induction of colitis.
Results:
In vitro anti-inflammatory effect observed by NMJ1 and NMJ2 by a significant decrease in pNF-κB
overexpression-induced by LPS. Similar effect was observed in anti-colitis responses by NMJ2 in both models by reversing
the colitis-induced changes in length, weight, antioxidant profile and histopathology of the colon.
Conclusion:
NMJ2 was found to be most effective among the tested compounds as an anti-inflammatory agent in both in
vitro and in vivo inflammatory studies.
Uncoupling proteins (UCPs) are identified as carriers of proton ions between the mitochondrial inner membrane and the mitochondrial matrix. ATP is mainly generated through oxidative phosphorylation in mitochondria. The proton gradient is generated across the inner mitochondrial membrane and the mitochondrial matrix, which facilitates a smooth transfer of electrons across ETC complexes. Until now, it was thought that the role of UCPs was to break the electron transport chain and thereby inhibit the synthesis of ATP. UCPs allow protons to pass from the inner mitochondrial membrane to the mitochondrial matrix and decrease the proton gradient across the membrane, which results in decreased ATP synthesis and increased production of heat by mitochondria. In recent years, the role of UCPs in other physiological processes has been deciphered. In this review, we first highlighted the different types of UCPs and their precise location across the body. Second, we summarized the role of UCPs in different diseases, mainly metabolic disorders such as obesity and diabetes, cardiovascular complications, cancer, wasting syndrome, neurodegenerative diseases, and kidney complications. Based on our findings, we conclude that UCPs play a major role in maintaining energy homeostasis, mitochondrial functions, ROS production, and apoptosis. Finally, our findings reveal that mitochondrial uncoupling by UCPs may treat many diseases, and extensive clinical studies are required to meet the unmet need of certain diseases.
The second most common cancer in both males and females is lung cancer. Chemotherapeutic resistance is the main problem associated with the treatment of lung cancer. Radiation therapy and surgery also produce recurrence in lung cancer patients; this shows the need to develop novel agents acting on new targets. A never in mitosis (NIMA)-related kinase 2 (NEK2) is a serine/threonine kinase associated with the family of NIMA-related kinase (NEK). NEK2 plays an important role in the regulating mitotic processes, such as centrosome duplication and separation, kinetochore attachment, spindle assembly checkpoint, and microtubule stabilization. Several in vitro, in vivo, and clinical studies have confirmed the overexpression of NEK2 in various types of cancers including lung cancer. Overexpression of NEK2 in non-small cell lung cancer (NSCLC) cells increased cell proliferation and chromosomal instability. The overexpression of NEK2 results in the activation of its downstream proteins such as β-catenin, MAD2, Hec1, rootletin, C-Nap1, CDC20, Cep68, and Sgo1. Activation of the Akt, β-catenin, and Wnt pathways could promote growth and metastasis of lung cancer cells. Such confirmation suggests that NEK2 is a novel target for treating many cancers including lung cancer. The current review provides an idea about functions and regulation of NEK2 and emphasizes about the role of NEK2 in lung cancer by discussing in vitro, in vivo, and clinical studies pertaining to the same.
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