<![CDATA[Hepatolenticular Degeneration]]> https://secure.eurekaselect.com RSS Feed for Disease Wise Article | BenthamScience EurekaSelect (+http://eurekaselect.com) Sat, 23 Nov 2024 10:57:28 +0000 <![CDATA[Hepatolenticular Degeneration]]> https://secure.eurekaselect.com https://secure.eurekaselect.com <![CDATA[Copper-Induced Epigenetic Changes Shape the Clinical Phenotype in Wilson’s Disease]]>https://secure.eurekaselect.comarticle/108755 <![CDATA[Current Drug Managements of Wilson’s Disease: From West to East]]>https://secure.eurekaselect.comarticle/72178 <![CDATA[Editorial (Thematic Selection: Strategies of Current Drugs and Alternative Treatments for Neurodegenerative Diseases)]]>https://secure.eurekaselect.comarticle/74860 <![CDATA[Aceruloplasminemia]]>https://secure.eurekaselect.comarticle/44583 <![CDATA[Metal Transport and Homeostasis within the Human Body: Toxicity Associated with Transport Abnormalities]]>https://secure.eurekaselect.comarticle/42745 <![CDATA[Evolution of Copper Transporting ATPases in Eukaryotic Organisms]]>https://secure.eurekaselect.comarticle/41715Copper is an essential nutrient for most life forms, however in excess it can be harmful. The ATP-driven copper pumps (Copper-ATPases) play critical role in living organisms by maintaining appropriate copper levels in cells and tissues. These evolutionary conserved polytopic membrane proteins are present in all phyla from simplest life forms (bacteria) to highly evolved eukaryotes (Homo sapiens). The presumed early function in metal detoxification remains the main function of Copper-ATPases in prokaryotic kingdom. In eukaryotes, in addition to removing excess copper from the cell, Copper-ATPases have another equally important function - to supply copper to copper dependent enzymes within the secretory pathway. This review focuses on the origin and diversification of Copper ATPases in eukaryotic organisms. From a single Copper ATPase in protozoans, a divergence into two functionally distinct ATPases is observed with the evolutionary appearance of chordates. Among the key functional domains of Copper-ATPases, the metal-binding Nterminal domain could be responsible for functional diversification of the copper ATPases during the course of evolution.

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<![CDATA[ Re-Wiring the Circuit: Mitochondria as a Pharmacological Target in Liver Disease]]>https://secure.eurekaselect.comarticle/20641

Through creating an analogy with a disrupted electric circuit gone bad, the present review focuses initially on how hepatic mitochondrial bioenergetics is affected in the context of drug and disease-induced liver failure and how targeting mitochondria with several antioxidant agents can be helpful for preventing the disruption of the mitochondrial electric circuit. ]]> <![CDATA[ Anti-Copper Therapies in Alzheimers Disease: New Concepts]]>https://secure.eurekaselect.comarticle/29931