Modulatory effects of Azadirachta indica leaf extract on cutaneous and hepatic biochemical status during promotion phase of DMBA/TPA-induced skin tumorigenesis in mice.

The modulation in biochemical status of skin and hepatic tissue at the time point of commencement of promotion stage of skin carcinogenesis in mice and its intervention with aqueous Azadirachta indica leaf extract (AAILE) were investigated. 7,12-Dimethylbenz(a)anthracene (DMBA, 500 nmol/100 ul of acetone) was applied topically for 2 weeks (twice weekly), followed by phorbol-12-myristate-13-acetate (TPA, 1.7 nmol/100 ul) twice weekly for 6 weeks on the depilated skin of mice and AAILE was administered orally at a dose level of 300 mg/kg body wt thrice a week for 10 weeks. DMBA/TPA treatment upregulated the phase I enzymes in skin and hepatic tissue, as revealed by the increased cytochrome P450 (CYP) and cytochrome b5 (cyt b5) levels and aryl hydrocarbon hydroxylase (AHH) activity when compared to the control group and differentially modulated the activities of phase II enzymes like glutathione-s-transferase (GST), DT-diaphorase (DTD) and uridine diphosphate glucuronosyltransferase (UDP-GT). AAILE treatment decreased the DMBA/TPA-induced increase in cutaneous CYP level and enhanced the DTD and UDP-GT activities when compared with DMBA/TPA group. In the hepatic tissue of AAILE + DMBA/TPA group, an increase in UDP-GT activity was observed when compared to DMBA/TPA group. DMBA/TPA treatment did not alter the skin lipid peroxidation (LPO) level when compared to control group, however, in the animals that received AAILE treatment along with DMBA/TPA, a significant increase in LPO was observed when compared to control group. This was associated with a decrease in cutaneous reduced glutathione (GSH) level of AAILE + DMBA/TPA group. Enhanced LPO level was observed in the hepatic tissue of DMBA/TPA and AAILE + DMBA/TPA groups when compared to control group. However, no alteration was observed in their hepatic GSH levels. The micronuclei score in hepatic tissue did not exhibit significant inter-group differences. The results of the present study suggest that apart from skin, liver may be affected during DMBA/TPA-induced skin tumorigenesis. AAILE treatment has the ability to modulate these changes potentially influencing the process of tumor formation. These findings seem to be important to carcinogenesis and its intervention with anti-cancer agents.

Environmental contaminants in pathogenesis of breast cancer.

This review is an attempt to comprehend the diverse groups of environmental chemical contaminants with a potential for pathogenesis of breast cancer, their probable sources and the possible mechanisms by which these environmental contaminants act and interplay with other risk factors. Estrogens are closely related to the pathogenesis of breast cancer. Oxidative catabolism of estrogen, mediated by various cytochrome P450 enzymes, generates reactive free radicals that can cause oxidative damage. The same enzymes of estrogenic metabolic pathways catalyze biological activation of several environmental (xenobiotic) chemicals. Xenobiotic chemicals may exert their pathological effects through generation of reactive free radicals. Breast tissue can be a target of several xenobiotic agents. DNA-reactive metabolites of different xenobiotic compounds have been detected in breast tissue. Many phase I and II xenobiotic metabolizing enzymes are expressed in both normal and cancerous breast tissues. These enzymes play a significant role in the activation/detoxification of xenobiotic and endogenous compounds including estrogens. More than 30 carcinogenic chemicals are present in tobacco smoke; many of them are fat-soluble, resistant to metabolism and can be stored in breast adipose tissue. Similarly, pesticides are also known to cause oxidative stress; while some act as endocrine disruptor, some are shown to suppress apoptosis in estrogen sensitive cell lines. Reports have shown an association of smoking (both active and passive) and pesticides with breast cancer risk. However, the issues have remained controversial. Different mutagenic substances that are generated in the cooking process e.g., heterocyclic amines and polycyclic aromatic hydrocarbons (PAHs) can be a threat to breast tissue. PAHs and dioxins exert their adverse effects through the aryl hydrocarbon receptor (AhR), which activates several genes involved in the metabolisms of xenobiotic compounds and endogenous estrogens. These chemicals also induce AhR-dependent mitochondrial dysfunction. Many of the environmental pollutants suppress the immune system, which are implicated to risk. A better understanding about the biological effects of different environmental carcinogenic compounds and determination of their impact on rising incidence of breast cancer will be beneficial in improving preventive policy against breast cancer.

Degradation of xenobiotic compounds by lignin-degrading white-rot fungi: enzymology and mechanisms involved.

White-rot fungi (WRF) are ubiquitous in nature with their natural ability to compete and survive. WRF are the only organisms known to have the ability to degrade and mineralize recalcitrant plant polymer lignin. Their potential to degrade second most abundant carbon reserve material lignin on the earth make them important link in global carbon cycle. WRF degrade lignin by its unique ligninolytic enzymatic machinery including lignin peroxidase, manganese peroxidase, laccase, cellobiose dehydrogenase, H2O2-generating enzymes, etc. The ligninolytic enzymes system is non-specific, extracellular and free radical based that allows them to degrade structurally diverse range of xenobiotic compounds. Lignin peroxidase and manganese peroxidase carry out direct and indirect oxidation as well as reduction of xenobiotic compounds. Indirect reactions involved redox mediators such as veratryl alcohol and Mn2+. Reduction reactions are carried out by carboxyl, superoxide and semiquinone radicals, etc. Methylation is used as detoxification mechanism by WRF. Highly oxidized chemicals are reduced by transmembrane redox potential. Degradation of a number of environmental pollutants by ligninolytic system of white rot fungi is described in the present review.

Modelo para el estudio de la actividad hepatotóxica en xenobióticos de origen vegetal / Method for the study of the acativity hepatotoxicity in xenobiotics of vegetable origin

La información etnofarmacológica que se tiene para enfrentar diversas patologías, debe ser validada para dar a los productos naturales más utilidad y eficacia, descartando toxicidad. Para demostrar la hepatotoxicidad en el presente estudio se recolectaron siete especies de la localidad de Charazani, provincia Baptista Saavedra (La Paz), las mismas que fueron clasificadas en el Herbario Nacional de Bolivia. Extractos acuosos de las especies se ensayaron en modelos i vivo, previa pruebas fitoquímicas. Los resultados alcanzados en este trabajo dieron lugar a la realización de una escala de hepatotoxicidad frente a controles: la Plumbagina, obtenida de fraccionamiento orgánico de Plumbago major y el Methamidophos (tamaron), un hepatotóxico potente. Se descarta la hepatotoxicidad de seis plantas trabajadas en extracto acuoso y sólo Baccharis sp. puede ser considerada como hepatotóxica comparada con valores de referencia