Showing posts with label metabolism of drugs. Show all posts
Thursday, 26 March 2015
Posted by Unknown
Leishmaniasis is a neglected disease affecting more than 12 million people worldwide. The most used drugs are pentavalent antimonials that are very toxic and display the problem of drug resistance, especially in endemic regions such as Bihar in India. For this reason, it is urgent to find new and less toxic drugs against leishmaniasis. To this end, the understanding of pathways affecting parasite survival is of prime importance for targeted drug discovery. The parasite survival inside the macrophage is strongly dependent on polyamine metabolism. Polyamines are, in fact, very important for cell growth and proliferation. In particular, spermidine (Spd), the final product of the polyamine biosynthesis pathway, serves as a precursor for trypanothione (N1,N8- bis(glutathionyl)spermidine, T(SH)2) and hypusine (Nε-(4-amino-2-hydroxybutyl)lysine). T(SH)2 is a key molecule for parasite defense against the hydrogen peroxide produced by macrophages during the infection. Hypusination is a posttranslational modification occurring exclusively in the eukaryotic initiation factor 5A (eIF5A), which has an important role in avoiding the ribosome stalling during the biosynthesis of protein containing polyprolines sequences. The enzymes, belonging to the spermidine metabolism of drugs, i.e. arginase (ARG), ornithine decarboxylase (ODC), S-adenosylmethionine decarboxylase (AdoMetDC), spermidine synthase (SpdS), trypanothione synthetase (TryS or TSA), trypanothione reductase (TryR or TR), tryparedoxin peroxidase (TXNPx), deoxyhypusine synthase (DHS) and deoxyhypusine hydroxylase (DOHH) are promising targets for the development of new drugs against leishmaniasis. This minireview furnishes a picture of the structural, functional and inhibition studies on polyamine metabolism enzymes that could guide the discovery of new drugs against leishmaniasis.
For a complete list, click on Bentham Science Publishers’ Journals Impacting Science
Saturday, 21 March 2015
Posted by Unknown
In this review, we discuss and compare studies of xenobiotic metabolism in both human skin and 3D human skin reconstructs. In comparison to the liver, the skin is a less studied organ in terms of characterising metabolic capability. While the skin forms the major protective barrier to environmental chemical exposure, it is also a potential target organ for adverse health effects. Occupational, accidental or intended-use exposure to toxic chemicals could result in acute or delayed injury to the skin (e.g. inflammation, allergy, cancer). Skin metabolism may play a role in the manifestation or amelioration of adverse effects via the topical route.
Today, we have robust testing strategies to assess the potential for local skin toxicity of chemical exposure. Such methods (e.g. the local lymph node assay for assessing skin sensitisation; skin painting carcinogenicity studies) incorporate skin metabolism of drugs implicitly in the in vivo model system used. In light of recent European legislation (i.e. 7th Amendment to the Cosmetics Directive and Registration Evaluation and Authorisation of existing Chemicals (REACH)), non-animal approaches will be required to reduce and replace animal experiments for chemical risk assessment. It is expected that new models and approaches will need to account for skin metabolism explicitly, as the mechanisms of adverse effects in the skin are deconvoluted. 3D skin models have been proposed as a tool to use in new in vitro alternative approaches. In order to be able to use 3D skin models in this context, we need to understand their metabolic competency in relation to xenobiotic biotransformation and whether functional activity is representative of that seen in human skin.
For a complete list, click on Bentham Science Publishers’ Journals Impacting Science
Monday, 16 March 2015
Posted by Unknown
Pharmacokinetic studies conducted in patients with CRF demonstrate that the nonrenal clearance of multiple drugs is reduced. Although the mechanism by which this occurs is unclear, several studies have shown that CRF affects the metabolism of drugs by inhibiting key enzymatic systems in the liver, intestine and kidney. The down-regulation of selected isoforms of the hepatic cytochrome P450 (CYP450) has been reported secondary to a decrease in gene expression. This is associated with major reductions in metabolism of drugs mediated by CYP450. The main hypothesis to explain the decrease in liver CYP450 activity in CRF appears to be the accumulation of circulating factors which can modulate CYP450 activity.
Liver phase II metabolic reactions are also reduced in CRF. On the other hand, intestinal drug disposition is affected in CRF. Increased bioavailability of several drugs has been reported in CRF, reflecting decrease in either intestinal first-pass metabolism of drugs (mediated by P-glycoprotein). Indeed, intestinal CYP450 is also down-regulated secondary to reduced gene expression, whereas, decreased intestinal P-glycoprotein activity has been described. Finally, although the kidneys play a major role in the excretion of drugs, it has the capacity to metabolize endogenous and exogenous compounds. CRF will lead to a decrease in the ability of the kidney to metabolize drugs, but the repercussions on the systemic clearance of drugs is still poorly defined, except for selected xenobiotics. In conclusion, reduced drug metabolism should be taken into account when evaluating the pharmacokinetics of drugs in patients with CRF.
For a complete list, click on Bentham Science Publishers’ Journals Impacting Science
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