This review presents a brief account of the discovery, importance, and use of selenium. Based in the importance of selenoproteins, their mechanism of reaction with the participation of selenium, as a selenol (-SeH) group, are indicated. Since the selenol group is the softest nucleophile center found in life, a brief discussion about the synthesis and possible antioxidant and selenoprotein mimetic effects of the organoselenium compounds that can generate the selenol group is presented.
The antagonism of mercury toxicity by selenium has been well documented. Mercury is a toxic metal, widespread in the environment. The main target organs (kidneys, lungs, or brain) of mercury vary depending on its chemical forms (inorganic or organic). Selenium is a semimetal essential to mammalian life as part of the amino acid selenocysteine, which is required to the synthesis of the selenoproteins. This chapter has the aim of disclosing the role of selenide or hydrogen selenide (Se or HSe) as central metabolite of selenium and as an important antidote of the electrophilic mercury forms (particularly, Hg and MeHg). Emphasis will be centered on the neurotoxicity of electrophile forms of mercury and selenium. The controversial participation of electrophile mercury and selenium forms in the development of some neurodegenerative disease will be briefly presented. The potential pharmacological use of organoseleno compounds (Ebselen and diphenyl diselenide) in the treatment of mercury poisoning will be considered. The central role of thiol (-SH) and selenol (-SeH) groups as the generic targets of electrophile mercury forms and the need of new in silico tools to guide the future biological researches will be commented.
This article presents the preparation and biological activities of new 5'-arylchalcogeno-3-aminothymidine derivatives as antioxidants (inhibition of lipid peroxidation, scavenging of the free radical 2,2-diphenylpicrylhydrazyl and demonstration of a thiol peroxidase-like activity) as well as antitumoral agents against bladder carcinoma 5637. The chalcogeno-aminothymidines presented prominent activity in the tests for both biological properties, showing a direct relation with the chalcogenium atom.
Background:
This study presents the synthesis and multi-target behavior of the new 5'-hydroxy-3-(chalcogenyl-triazoyl)-thymidine and the biological evaluation of these compounds as antioxidant and anti-HIV agents.
Objective:
Antiretroviral therapy induces oxidative stress. Based on this, the main objective of this manuscript is the preparation of compounds that combine anti-HIV and antioxidant activities.
Methods:
The compounds were prepared from commercially available AZT, through a copper-catalyzed Huisgen 1,3-dipolar cycloadditions exploiting the AZT azide group and chalcogenyl alkynes.
Results:
The chalcogenium-AZT derivatives were obtained in good yields via click chemistry. The compounds evaluated showed antioxidant and anti-HIV activity. Additionally, in vivo toxicity of this class of compounds was also evaluated and the representative nucleoside did not change the survival, behavior, biochemical hepatic, and renal markers compared to the control mice.
Conclusion:
Data suggest the feasibility of modifying the AZT nucleus with simple organochalcogen fragments, exploring the reactivity of the azide group via 1,3-dipolar Huisgen cycloaddition reaction. The design of these new compounds showed the initially desired biological activities.
The synthesis of chiral azido organochalcogenium compounds prepared from inexpensive and commerciallyavailable a-amino alcohols through diazo transfer reaction are disclosed. The products were obtained in good yields in a modulate synthetic route, affording an efficient methodology for preparing new chiral b-aryl-chalcogenium azide compounds. These com-pounds were evaluated for in vitro antitumoral lung carcinoma A549 as well as electrochemical and antioxidant assays. They presented prominent activities of apoptosis and cell cycle arrest induction as well as antioxidant properties. Additionally, the toxicities in vivo for the most effective compounds were evaluated and no overt sign of toxicity was observed.
BackgroundExposure to vinylcyclohexene (VCH) and methylmercury (MeHg+) can induce oxidative stress and gene modulation. Several studies have been evaluating the effects of VCH and MeHg+, but little is known about interactive effects between them. This work aimed to assess the exposure and co-exposure effects of MeHg+ and VCH on oxidative stress and gene modulation in Drosophila melanogaster.MethodsReactive species production, glutathione S-transferase (GST) and acetylcholinesterase (AChE) activities were evaluated after exposure and co-exposure to VCH (1 mM) and MeHg+ (0.2 mM) for one or three days in the head and body (thorax and abdomen) of flies. The expression of genes related to redox state and inflammatory response was evaluated after exposure and co-exposure to VCH and MeHg+ for three days.ResultsSurvival decreased only in flies co-exposed to VCH and MeHg+ for three days. All treatments increased total reactive species production after one day of exposure. However, no significant changes were observed in the head after three days of exposure. One day of exposure to VCH caused an increase in the head GST activity, whereas MeHg+ induced an increase after three days of exposure. Regarding the body, all treatments increased GST activity after one day of exposure, but only the flies exposed to MeHg+ presented an increase in GST activity after three days of exposure. Treatments did not alter AChE activity in the head. As for gene expression, there was a significant increase in the Relish transcription factor gene in the flies’ body, but Nrf2, Keap1, Jafrac1, TrxR1, and NF-κβ were not altered.ConclusionThe results suggest that exposure to VCH and MeHg+ induce oxidative stress and activation of an inflammatory response in fruit flies.
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