Ethnobotanical inventory and medicinal uses of some important woody plant species of Kotli,Azad Kashmir,Pakistan

To document ethnobotanical informations of useful woody plant species in the region of Kotli, Azad Kashmir.MethodsAn ethnobotanical survey was conducted in Kotli. Data were collected by interview and semi structured questionnaire from selected local informants and traditional practitioners as well as by field assessment.ResultsThe present study documented the etnobotanical uses of 33 woody plant species. Most of the species have been used for dual purpose. Only 5 species are used for one purpose. Study revealed all species have medicinal value, among which 21 were used as fuel wood species, 16 as fodder species, 4 as timber wood species, 12 as edible fruit species, 6 as fence or hedge plant, 7 as ornamental species and 12 species had other uses.ConclusionsMedicinal plants are still widely used for health care by locals of Kotli. Some species of woodlands seem to be vulnerable to overcollection and deforestation. As the young generation is diverted toward allelopathic medicines, ethnobotanical knowledges of important medicinal plants are restricted to the old people only. It is suggested to close the forest of district Kotli for next two to three decades for the conservation of plant biodiversity.     

对医学论著中实验动物种类与数量分布的探讨

目的:掌握论著研究对象中实验动物的种类及数量,为实验动物的数量提供和管理评价提供依据。方法:阅读武警医学院学报论著内容,记录研究对象中实验动物的种类和数量。结果:在刊载的791篇论著中,有183篇涉及动物实验,占23.14%。实验动物的总需求量为7 612只。结论:在实验动物的饲养和管理上要着眼于医学科学研究的需要,确保实验动物的种类、数量和质量。     

Diet components can suppress inflammation and reduce cancer risk

Epidemiology studies indicate that diet or specific dietary components can reduce the risk for cancer, cardiovascular disease and diabetes. An underlying cause of these diseases is chronic inflammation. Dietary components that are beneficial against disease seem to have multiple mechanisms of action and many also have a common mechanism of reducing inflammation, often via the NFκB pathway. Thus, a plant based diet can contain many components that reduce inflammation and can reduce the risk for developing all three of these chronic diseases. We summarize dietary components that have been shown to reduce cancer risk and two studies that show that dietary walnut can reduce cancer growth and development. Part of the mechanism for the anticancer benefit of walnut was by suppressing the activation of NFκB. In this brief review, we focus on reduction of cancer risk by dietary components and the relationship to suppression of inflammation. However, it should be remembered that most dietary components have multiple beneficial mechanisms of action that can be additive and that suppression of chronic inflammation should reduce the risk for all three chronic diseases.     

Ethnobotanical Study of Medicinal Plants Used by Kurd Tribe in Dehloran and Abdanan Districts,Ilam Province,Iran

This paper provides significant ethnobotanical information on pharmaceutical plant uses, where some degree of acculturation exists, so that there is urgency in recording such data. The aim of this work is to catalogue, document, and make known the uses of plants for folk medicine in Dehloran and Abdanan districts, Ilam Province, Iran. An analysis was made of the species used, parts of the plant employed, preparation methods, administration means, and the ailments treated in relation to pathological groups. A folk botanical survey was carried out from February 2007 to October 2009. The information was collected from 81 persons (60% men and 40% women) in 20 villages. The informants reported data on 122 species, belonging to 49 botanical families, were claimed as medicinal. This work is focused on human medicinal plant uses, which represent 95% of the pharmaceutical uses. The most commonly represented families were Asteraceae (37.5%), Lamiaceae (20.8%), Rosaceae (18.7%), Fabaceae (16.7%) and Apiaceae (14.6%). Some of the uses were found to be new when compared with published literature on ethnomedicine of Iran. The folk knowledge about medicinal plant use is still alive in the studied region, and a number of scarcely reported plant uses has been detected, some of them with promising phytotherapeutical applications. The results of the study reveal that some of species play an important role in primary healthcare system of these tribal communities.     

Antinociceptive and anti-inflammatory activities of Tabernaemontana catharinensis

In this work we describe the analgesic, anti-inflammatory and toxic activities as well as the phytochemical profile of the ethanol extract from Tabernaemontana catharinensis A. DC. (Apocynaceae) stem bark. Analgesic evaluation was carried out against chemical and thermal stimuli. Anti-inflammatory activity was investigated on carrageenan-induced edema in rats and toxicological studies (LD₅₀) were conducted in mice. Phytochemical analyses were performed by standardized methodology. In an analgesic assay, acetic acid-induced writhings were significantly inhibited by extract doses of 37.5?mg/kg (40.97%), 75?mg/kg (77.70%) and 150?mg/kg (88.98%). A central analgesia was also observed using T. catharinensis extract at all doses tested, particularly noticed at 60 and 90?min following administration. The extract significantly reduced edema development by 30.35% (37.5?mg/kg), 34.46% (75?mg/kg), and 56.42% (150?mg/kg) when assessed 180?min following carrageenan intraplantar injection, demonstrating an effective anti-inflammatory action. The LD₅₀ value was 2200?mg/kg. Phytochemical analyses of ethanol extract from Tabernaemontana catharinensis stem bark showed the presence of alkaloids and terpenoids, which may be responsible for the observed pharmacological activities described in this work.     

Improved lipid profile and increased serum antioxidant capacity in healthy volunteers after Sambucus ebulus L. fruit infusion consumption

This study aimed to establish the effect of Sambucus ebulus L. (SE) ripe fruit infusion on body weight, blood pressure, glucose levels, lipid profile and antioxidant markers in healthy volunteers in respect of its possible protective activity against cardiovascular diseases and other oxidative stress-related diseases. The study involved 21 healthy volunteers, aged between 20 and 59, BMI 23.12?±?1.31, who consumed 200?ml SE infusion/day for a period of 30?d. Blood samples were collected before and at the end of the intervention. Significant decrease in triglycerides (14.92%), total cholesterol (15.04%) and LDL-C (24.67%) was established at the end of the study. In addition, HDL-C/LDL-C ratio increased by 42.77%. Improved serum antioxidant capacity and total thiol levels were also established. The results presented in this first human intervention study with SE fruit infusion indicate the potential of the plant to improve lipid profile and serum antioxidant capacity in humans.     

A unique AtSar1D-AtRabD2a nexus modulates autophagosome biogenesis in Arabidopsis thaliana

In eukaryotes, secretory proteins traffic from the endoplasmic reticulum (ER) to the Golgi apparatus via coat protein complex II (COPII) vesicles. Intriguingly, during nutrient starvation, the COPII machinery acts constructively as a membrane source for autophagosomes during autophagy to maintain cellular homeostasis by recycling intermediate metabolites. In higher plants, essential roles of autophagy have been implicated in plant development and stress responses. Nonetheless, the membrane sources of autophagosomes, especially the participation of the COPII machinery in the autophagic pathway and autophagosome biogenesis, remains elusive in plants. Here, we provided evidence in support of a novel role of a specific Sar1 homolog AtSar1d in plant autophagy in concert with a unique Rab1/Ypt1 homolog AtRabD2a. First, proteomic analysis of the plant ATG (autophagy-related gene) interactome uncovered the mechanistic connections between ATG machinery and specific COPII components including AtSar1d and Sec23s, while a dominant negative mutant of AtSar1d exhibited distinct inhibition on YFP-ATG8 vacuolar degradation upon autophagic induction. Second, a transfer DNA insertion mutant of AtSar1d displayed starvation-related phenotypes. Third, AtSar1d regulated autophagosome progression through specific recognition of ATG8e by a noncanonical motif. Fourth, we demonstrated that a plant-unique Rab1/Ypt1 homolog AtRabD2a coordinates with AtSar1d to function as the molecular switch in mediating the COPII functions in the autophagy pathway. AtRabD2a appears to be essential for bridging the specific AtSar1d-positive COPII vesicles to the autophagy initiation complex and therefore contributes to autophagosome formation in plants. Taken together, we identified a plant-specific nexus of AtSar1d-AtRabD2a in regulating autophagosome biogenesis.

Autophagy is a conserved catabolic process characterized by the de novo generation of a double-membrane structure called an autophagosome with a fundamental function in the bulk turnover of cytoplasmic components, including proteins, RNAs, and organelles. Genetic studies in yeast have elucidated the molecular machinery of autophagy, whereby 42 autophagy-related (ATG) genes have been identified (1–3). These ATG genes are highly conserved among eukaryotes but often have multiple isoforms in other higher organisms, in particular in sessile plants. Albeit increasing understanding on the molecular function of Atg proteins in acting hierarchically on the phagophore assembly site (PAS) to produce autophagosomes, the origin of the autophagosomal membrane remains unclear in higher eukaryotes. Furthermore, the dedication of other membranes and machineries in the autophagy pathway remains under investigation.Plant autophagy is known to play important roles in the sessile lifestyle of plants, participating in seed germination, seedling establishment, plant development, hormone responses, lipid metabolism, and reproductive development (4). Plant autophagy research is advancing with findings not only on the counterparts of the yeast/mammalian Atg proteins but also dealing with some plant-unique factors functioning in different steps of autophagosome biogenesis, thereby uncovering novel mechanisms that might or might not be conserved in nonplant species (5). More interestingly, higher plants possess multiple protein isoforms of ATG machinery, whose functional heterogeneity in the autophagy pathway has only recently been unveiled (6).The coat protein complex II (COPII) machinery consists of five cytosolic components: the small GTPase Sar1, the inner coat protein dimer Sec23-Sec24, and the outer coat proteins Sec13-Sec31. These proteins are essential for COPII-coated vesicle formation, which buds from specialized regions of the ER, namely ER exit sites (ERESs) (7). Under nutrient-rich conditions, COPII vesicles mediate anterograde ER to Golgi transport. However, increasing evidence from yeast and mammals suggests that the COPII machinery or even COPII vesicles themselves may contribute to autophagosome formation when cells are starved for nutrients (8–16). Gene duplication events have occurred substantially in sessile plants during evolution, and the importance of distinct paralogs in environmental stress adaptation during plant development has been implied (17). Arabidopsis encodes multiple COPII paralogs in its genome, including five Sar1s, seven Sec23s, three Sec24s, two Sec13s, and two Sec31s (17). Increasing numbers of studies have pinpointed the functional diversity and importance of distinct COPII paralogs in ER protein export (18–23). Nonetheless, the mechanism by which COPII vesicles are redirected to the autophagy pathway upon nutrient starvation, and their roles in autophagosome biogenesis, remains unclear. Furthermore, the participation of specific COPII paralogs in autophagy regulation remains unknown in plants.Here, we report on a role of a specific Sar1 homolog, AtSar1d, that modulates plant autophagosome biogenesis in concert with AtRabD2a. Large-scale proteomic analysis of the ATG interactome has revealed possible mechanistic connections between the ATG machinery and specific COPII components in plants. Cellular and biochemical analyses have shown that the dominant negative (DN) mutant of AtSar1d (AtSar1dDN) specifically perturbs YFP-ATG8 vacuolar degradation upon autophagic induction. Consistently, a transfer DNA (T-DNA) insertion mutant of AtSar1d exhibited starvation-related phenotypes. Notably, AtSar1d regulates autophagosome progression through specific recognition of ATG8e by a previously uncharacterized noncanonical motif. We further identify a plant-unique Rab1/Ypt1 homolog AtRabD2a that colocalizes with AtSar1d and ATG8 upon starvation by transient expression in Arabidopsis protoplasts. A DN mutant of AtRabD2a (AtRabD2aNI) perturbs autophagy flux, while AtRabD2a is indispensable for bridging the AtSar1d-positive COPII vesicles with the ATG1 complex, thus contributing to autophagosome biogenesis in plants. Our study therefore unequivocally demonstrates that the plant-specific COPII machinery regulates autophagosome biogenesis and sheds light on the evolutionary importance of gene duplication events in the plant autophagy pathway.