Metabolite profiling and in vitro biological activities of two commercial bitter melon (Momordica charantia Linn.) cultivars.

The current study was designed to characterize the metabolite profile and bioactivity of two commercial bitter melon (Momordica charantia Linn.) genotypes. UPLC-high resolution mass spectrometry (HRMS) was used to identify 15 phenolic and 46 triterpenoids in various bitter melon extracts. Total phenolic levels were the highest (57.28 ±â€¯1.02) in methanolic extract of the inner tissue of Indian Green cultivar, which also correlated to the highest DPPH radical scavenging activity (30.48 ±â€¯2.49 ascorbic acid equivalents (mg of AAE)/g of FD). In addition, highest levels of total saponins were observed in chloroform extract of the Chinese bitter melon pericarp (75.73 mg ±â€¯4.67 diosgenin equivalents (DE)/g of FD). Differential inhibition of α-amylase and α-glucosidase activity was observed in response to polarity of extract, cultivar and tissue type. These results suggest that consumption of whole bitter melon may have potential health benefits to manage diabetes.

Extratos vegetais no controle da antracnose e na conservação da qualidade em frutos de mamoeiro / Plant extracts in controlling anthracnose and quality conservation in papayas fruit

RESUMO O presente trabalho teve como objetivo avaliar a ação antifúngica dos extratos de Allamanda blanchetti A.DC. e Momordica charantia L. no controle de Colletotrichumgloesporioides e qualidade pós-colheita em frutos de mamoeiro da cultivar Sunrise solo. Os experimentos foram conduzidos nos Laboratório de Fitopatologia e Laboratório de Produtos de Origem Animal, CCA-UFPB, Campus.II, Areia-PB. Os frutos foram colhidos no estádio 1 de maturação, em seguida, sanitizados com hipoclorito de sódio a 1% por três minutos e pulverizados com os extratos etanólicos de A. blanchetti e M. charantia nas concentrações: 0, 10, 100, 500 e 1000 µg.mL-1. Os frutos foram distribuídos em bandejas de polipropileno expandido em temperatura ambiente (23±2 °C) e umidade relativa em torno de 70%. Após doze dias de armazenamento, os frutos foram avaliados quanto à incidência natural de C. gloesporioides, severidade, atividade da enzima peroxidase, sólidos solúveis, acidez titulável, relação SS/AT, perda de massa e aparência externa dos frutos. Foi realizada análise de regressão polinomial testando modelos até o terceiro grau para as concentrações dos extratos utilizando análise de variância pelo teste F enquanto as médias foram comparadas pelo teste de Tukey a 5% de probabilidade, através do programa SAS® 9.2. Não se observou diferença estatística quando avaliou-se a incidência natural de C. gloesporioides em frutos de mamoeiro utilizando os extratos de A. blanchetti e M. charantia. Já na avaliação da severidade da antracnose, verificou-se diferença para o tratamento com o extrato de A. blanchetti, que apresentou as menores escalas de notas em relação ao tratamento com a M. charantia. Observou-se atividade da peroxidase (POD) em frutos de mamoeiro nos extratos de A. blanchetti e M. charantia. Os frutos tratados com A. blanchetti apresentaram teor de acidez, com máximo de 0,12 g de ácido cítrico.100 g-1 e no de M. charantiaapresentou aumento para 0,15 g de ácido cítrico.100 g-1. A relação SS/AT diminuiu com o aumento das concentrações dos dois extratos. Os frutos tratados com A. blanchetti apresentaram maior perda de massa durante todo o armazenamento, sendo maior que 10% aos nove dias. Já a perda de massa dos frutos tratados com M. charantia apresentou comportamento linear, sendo superior a 12% aos 12 dias de armazenamento. A cor evoluiu de 1 (verde) para 6 (casca alaranjada) e a aparência dos frutos diminuiu com o decorrer do tempo de 5 (excelente) para 3 (regular) em todas concentrações dos extratos de A. blanchetti e M. charantia. Os extratos de A. blanchetti e M. charantia não reduziram a incidência natural, porém, só o extrato de A. blanchetti foi responsável por reduzir a severidade da antracnose. Ocorreu a atividade da enzima peroxidase em todos os tratamentos avaliados e conservaram a qualidade pós-colheita em frutos até os nove dias de armazenamento.

ABSTRACT This study aimed to evaluate the antifungal effect of the extracts Allamandablanchetti A.DC. and Momordica charantia L. in the control of Colletotrichum gloesporioides in papaya fruits of the Sunrise Solo cultivation, as well as their post-harvest quality. The trials were conducted in the Laboratory of Plant Pathology and Animal Products Laboratory, CCA-UFPB, Campus II, Areia-PB. The fruits were harvested at maturity stage 1, then sanitized with sodium hypochlorite 1% for three minutes and sprayed with ethanol extracts of A. blanchetti and M.charantia at concentrations of 0, 10, 100, 500 and 1000 μg.mL-1.The fruits were distributed in polypropylene trays expanded at room temperature (23±2 °C) and relative humidity around 70%. After twelve days of storage, the fruits were evaluated for natural incidence of C. gloesporioides, severity, peroxidase enzyme activity, soluble solids, titratable acidity, SS/TA ratio, weight loss and external appearance of the fruit. Polynomial regression testing models to the third degree were employed for the extracts of concentrations, using analysis of variance by F test. The averages were compared by Tukey test at 5% probability, through the SAS® 9.2 program. There was no statistical difference observed when we evaluated the natural incidence of C. gloesporioides in the papaya fruit, using extracts from A. blanchetti and M. charantia. In the assessment of the severity of the anthracnose, there was no statistical difference for the treatment with the extract of A. blanchetti, which had smaller scales of notes when compared with the treatment using the M. charantia. It was observed peroxidase activity (POD) in the papaya fruits treated with the extracts of A. blanchetti and M. charantia. The fruits treated with A. blanchetti presented a maximum dose of acidity of 0.12 g g-1 of citric acid.100 g-1. In the fruits treated with M. charantia this increase was of 0.15g of citric acid.100 g-1. The SS/TA ratio decreased with increasing concentrations of the two extracts. The fruits treated with A. blanchettipresented higher weight loss of approximately 10%, since the M. charantia was over 12%. The color evolved from 1 (green) to 6 (Orange Peel) and the appearance of the fruit got worse according to the time, from 5 (excellent) to 3 (regular) in all the concentrations of the extracts of A. blanchetti and M. charantia. The A. blanchetti and M. charantia extracts did not reduce the natural incidence, however, only the A. blanchetti extract was able to decrease the severity of the anthracnose. The peroxidase enzyme presented activity in all treatments and kept the postharvest quality of the fruits in the nine days of storage.

Greenhouse-grown bitter melon: production and quality characteristics.

BACKGROUND: Bitter melon (Momordica charantia L.) is a medicinal fruit reported to have antidiabetic properties. To grow this tropical fruit year-round in temperate climates, greenhouse production is necessary, sometimes without insect pollinators. Suitable high-yielding varieties with good bioactivity need to be identified. This experiment evaluated the yield of six varieties of bitter melon under greenhouse conditions and their bioactivity in terms of total phenolic and saponin compounds and total antioxidant activity determined using four assays. RESULTS: The larger varieties (Big Top Medium, Hanuman, Jade and White) were more productive than the small varieties (Indra and Niddhi) in terms of total fruit weight and yield per flower pollinated. The bioactivity (total phenolic and saponin compounds and antioxidant activity) of the two small varieties and Big Top Medium was significantly higher than that of the other three large varieties. Two antioxidant assays, 2,2-diphenyl-1-picrylhydrazyl (DPPH) and ferric-reducing antioxidant power (FRAP), were shown to provide the strongest correlations with phenolic and saponin compounds of bitter melon. CONCLUSION: Preliminary research has identified Big Top Medium as the most suitable variety for greenhouse production. The rich source of phenolic and saponin compounds and their associated antioxidant activity highlight bitter melon as a valuable food.

Introgression between cultivars and wild populations of Momordica charantia L. (Cucurbitaceae) in Taiwan.

The landrace strains of Momordica charantia are widely cultivated vegetables throughout the tropics and subtropics, but not in Taiwan, a continental island in Southeast Asia, until a few hundred years ago. In contrast, the related wild populations with smaller fruit sizes are native to Taiwan. Because of the introduction of cultivars for agricultural purposes, these two accessions currently exhibit a sympatric or parapatric distribution in Taiwan. In this study, the cultivars and wild samples from Taiwan, India, and Korea were collected for testing of their hybridization and evolutionary patterns. The cpDNA marker showed a clear distinction between accessions of cultivars and wild populations of Taiwan and a long divergence time. In contrast, an analysis of eight selectively neutral nuclear microsatellite loci did not reveal a difference between the genetic structures of these two accessions. A relatively short divergence time and frequent but asymmetric gene flows were estimated based on the isolation-with-migration model. Historical and current introgression from cultivars to wild populations of Taiwan was also inferred using MIGRATE-n and BayesAss analyses. Our results showed that these two accessions shared abundant common ancestral polymorphisms, and the timing of the divergence and colonization of the Taiwanese wild populations is consistent with the geohistory of the Taiwan Strait land bridge of the Last Glacial Maximum (LGM). Long-term and recurrent introgression between accessions indicated the asymmetric capacity to receive foreign genes from other accessions. The modern introduction of cultivars of M. charantia during the colonization of Taiwan by the Han Chinese ethnic group enhanced the rate of gene replacement in the native populations and resulted in the loss of native genes.