15 research outputs found

    Involvement of the p62/NRF2 signal transduction pathway on erythrophagocytosis

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    This deposit is composed by the main article plus the supplementary materials of the publication.Erythrophagocytosis, the phagocytic removal of damaged red blood cells (RBC), and subsequent phagolysosome biogenesis are important processes in iron/heme metabolism and homeostasis. Phagolysosome biogenesis implies the interaction of nascent phagosomes with endocytic compartments and also autophagy effectors. Here, we report that besides recruitment of microtubule-associated protein-1-light chain 3 (LC3), additional autophagy machinery such as sequestosome 1 (p62) is also acquired by single-membrane phagosomes at very early stages of the phagocytic process and that its acquisition is very important to the outcome of the process. In bone marrow-derived macrophages (BMDM) silenced for p62, RBC degradation is inhibited. P62, is also required for nuclear translocation and activation of the transcription factor Nuclear factor E2-related Factor 2 (NRF2) during erythrophagocytosis. Deletion of the Nrf2 allele reduces p62 expression and compromises RBC degradation. In conclusion, we reveal that erythrophagocytosis relies on an interplay between p62 and NRF2, potentially acting as protective mechanism to maintain reactive oxygen species at basal levels and preserve macrophage homeostasis.Fundação para a Ciência e a Tecnologia grants: (HMSP-ICT/0024/2010, UID/Multi/04462/2013, SFRH/BD/62197/2009, SFRH/BD/90258/2012, SFRH /BD/51877/2012, SFRH/BD/52293/2013, PTDC/SAU-TOX/116627/2010, HMSP-ICT/0022/2010 ); European Union FEDER support: (COMPETE, QREN, PT2020 Partnership Agreement), ERC grant: (ERC-2011-AdG 294709-DAMAGECONTROL).info:eu-repo/semantics/publishedVersio

    Indigenous use and bio-efficacy of medicinal plants in the Rasuwa District, Central Nepal

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    <p>Abstract</p> <p>Background</p> <p>By revealing historical and present plant use, ethnobotany contributes to drug discovery and socioeconomic development. Nepal is a natural storehouse of medicinal plants. Although several ethnobotanical studies were conducted in the country, many areas remain unexplored. Furthermore, few studies have compared indigenous plant use with reported phytochemical and pharmacological properties.</p> <p>Methods</p> <p>Ethnopharmacological data was collected in the Rasuwa district of Central Nepal by conducting interviews and focus group discussions with local people. The informant consensus factor (F<sub>IC</sub>) was calculated in order to estimate use variability of medicinal plants. Bio-efficacy was assessed by comparing indigenous plant use with phytochemical and pharmacological properties determined from a review of the available literature. Criteria were used to identify high priority medicinal plant species.</p> <p>Results</p> <p>A total of 60 medicinal formulations from 56 plant species were documented. Medicinal plants were used to treat various diseases and disorders, with the highest number of species being used for gastro-intestinal problems, followed by fever and headache. Herbs were the primary source of medicinal plants (57% of the species), followed by trees (23%). The average F<sub>IC</sub> value for all ailment categories was 0.82, indicating a high level of informant agreement compared to similar studies conducted elsewhere. High F<sub>IC </sub>values were obtained for ophthalmological problems, tooth ache, kidney problems, and menstrual disorders, indicating that the species traditionally used to treat these ailments are worth searching for bioactive compounds: <it>Astilbe rivularis</it>, <it>Berberis asiatica</it>, <it>Hippophae salicifolia, Juniperus recurva</it>, and <it>Swertia multicaulis</it>. A 90% correspondence was found between local plant use and reported plant chemical composition and pharmacological properties for the 30 species for which information was available. Sixteen medicinal plants were ranked as priority species, 13 of which having also been prioritized in a country-wide governmental classification.</p> <p>Conclusions</p> <p>The <it>Tamang </it>people possess rich ethnopharmacological knowledge. This study allowed to identify many high value and high priority medicinal plant species, indicating high potential for economic development through sustainable collection and trade.</p

    Chemical and Biological Mechanisms of Phytochemical Activation of NRF2 and Importance in Disease Prevention

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    Bioproduction of Anticancer Podophyllotoxin and Related Aryltretralin-Lignans in Hairy Root Cultures of Linum Flavum L.

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    Podophyllotoxin (PPT) is the unique natural precursor of Etoposide, a topoisomerase II inhibitor drug, used in more than a dozen anticancer chemotherapy treatments. Etoposide is appearing on the list of essential medicines of the World Health Organization. PPT is still exclusively extracted from the rhizome of Podophyllum species, its main natural source. The supply of Podophyllum hexandrum plants is limited, since the occurrence of these plant species is scarce, collection is destructive, and the plants need a long regeneration period. As a consequence, this species is now endangered and listed on Appendix II of the Convention on International Trading of Endangered Species. Chemical synthesis of PPT is difficult due to the presence of four contiguous chiral centers and the presence of a base sensitive trans-lactone moiety. Alternatives are being actively searched, but so far, no wild plants have been described with similar PPT production capacity as compared to Podophyllum. However, several plants producing PPT or other related aryltetralin lignans (ATL) have been identified in recent decades, including the Linaceae. Given its high lignan accumulation capacity, Linum flavum is considered a promising alternative source of PPT and other related ATL. However, unlike the common flax L. usitatissimum, L. flavum has a low agricultural potential (e.g., slow growth and dehiscence of fruits). Therefore, in vitro cultures of plant cells and/or tissues provide an interesting alternative to whole L. flavum plants for the production of these valuable ATL. In particular, L. flavum hairy roots (HRs) accumulate high levels of ATL and it is also possible to further increase this ATL accumulation by the selection of the best genotype, optimization of cultures media and conditions and choice of carbon sources, use of plant growth regulators, elicitor treatments, or precursors’ addition. To date, the ATL accumulation levels can still be perceived insufficient for L. flavum HRs before being used as a commercially viable biotechnological production system. To reach this goal, a better knowledge of the mechanisms that regulate the metabolic flux of intermediates in the different branches of the ATL metabolic pathway will be an important prerequisite to direct the biosynthesis toward the production of a high amount of the desired PPT. In the future, metabolic engineering aiming at constructing the PPT pathway in a heterologous host is very appealing, but for that approach in-depth knowledge of the biosynthetic pathway toward PPT and other related ATL is necessary
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