Crude extract of the tropical tree Gallesia integrifolia (Phytolaccaceae) for the control of Aedes aegypti (Diptera: Culicidae) larvae / Extracto crudo del árbol tropical Gallesia integrifolia (Phytolaccaceae) para el control de larvas de Aedes aegypti (Diptera: Culicidae)

Introduction: Phytoinsecticides are alternatives to control insects in different stages, Gallesia integrifolia (Spreng.) Harms, Phytolacaceae family, popularly known as pau d'alho, garlic tree, and guararema in Brazil, is known due to its strong alliaceous odor because of the presence of sulfur molecules in the plant. This species presents biological activity and potential insecticide effect that is still unexploited. Objective: This study aimed to evaluate the biological activity of the ethanolic crude extract from G. integrifolia leaves, flowers, and fruits on the control of Aedes aegypti third-stage larvae and pupae. Methods: The botanical material was collected in city Umuarama, Paraná, Brazil at the coordinates (23º46'16" S & 53º19'38" WO), and altitude of 442 m, the fruits of G. integrifolia were collected in May and the leaves and flowers in December 2017. The crude extracts of G. integrifolia leaves, flowers, and fruits were prepared by dynamic maceration technique. The chemical composition of the extracts was determined by gas chromatography coupled to a mass spectrometry. The insecticidal activity of the crude extracts of G. integrifolia were carried out on larvae and pupae of A. aegypti in concentrations between 0.001 to 25 000 mg/mL, and afterwards the lethal concentrations that kill 50 % (LC50) and 99.9 % (LC99.9) were determined by probit analysis. Anticholinesterase activity was determined by bioautographic method at concentrations from 0.000095 to 50 mg/mL. Results: The yield of G. integrifolia crude extracts were 8.2, 9.1, and 17.3 % for flowers, fruits, and leaves, respectively. The chemical composition of G. integrifolia extracts was characterized by presence of fatty acid esters, phytosterols, vitamins, oxygenated diterpenes and organosulfur compounds. The flower extract presented the high amount of sulfur compounds (20.2 %) such as disulfide, bis (2-sulfhydryl ethyl) (11.9 %), 2,3,5-trithiahexane (6.2 %), 1,2,4-trithiolane (1.1 %), and 2,4-dithiapentane (1.1 %). Regarding the insecticidal activity, flower extract showed highly active with LC99.9 of 0.032 mg/mL and LC99.9 of 0.969 mg/mL on A. aegypti larvae and pupae, respectively, and the highest inhibition of acetylcholinesterase enzyme (0.00019 mg/mL) ex situ. The flower extract presented anticholinesterase and larvicide activity, respectively, 12.8 % and 35.6 % greater than the control temephos. Conclusions: This study opens new perspectives on the use of extracts from G. integrifolia as a bioinsecticide alternative for the control of A. aegypti larvae and pupae.

Introducción: Los fitoinsecticidas son alternativas para el control de insectos en diferentes etapas, Gallesia integrifolia (Spreng.) Harms, familia Phytolacaceae, conocida popularmente como pau d'alho, árbol de ajo y guararema en Brasil, es conocida por su fuerte olor aliáceo debido a la presencia de moléculas de azufre en la planta. Esta especie presenta actividad biológica y potencial efecto insecticida que aún no está explotado. Objetivo: El objetivo de este estudio fue evaluar la actividad biológica del extracto crudo etanólico de las hojas, flores y frutos de G. integrifolia en el control de las larvas y pupas de la tercera etapa de Aedes aegypti. Métodos: El material botánico fue recolectado en la ciudad de Umuarama, Paraná, Brasil (23º46'16" S & 53º19'38" W), a una altitud de 442 m y los frutos de G. integrifolia fueron recolectados en mayo de 2017 y las hojas y flores en diciembre del mismo año. Los extractos crudos de hojas, flores y frutos de G. integrifolia se prepararon por técnica de maceración dinámica. La composición química de los extractos se determinó por cromatografía de gases acoplada a espectrometría de masas. La actividad insecticida de los extractos crudos de G. integrifolia fue evaluada en larvas y pupas de A. aegypti en concentraciones entre 0.001 a 25 000 mg/mL, y las concentraciones letales que matan 50 % (CL50) y 99.9 % (CL99.9) de larvas fueron determinados por análisis de probit. La actividad anticolinesterasa fue evaluada por método bioautográfico en concentraciones de 0.000095 a 50 mg/mL. Resultados: El rendimiento de los extractos crudos de G. integrifolia fue de 8.2, 9.1 y 17.3 % para flores, frutos y hojas, respectivamente. La composición química de los extractos de G. integrifolia se caracterizó por la presencia de ésteres de ácidos grasos, fitosteroles, vitaminas, diterpenos oxigenados y compuestos organosulfurados. El extracto de las flores presentó alta cantidad de compuestos de azufre (20.2 %) como disulfuro, bis(2-sulfhidril etilo) (11.9 %), 2,3,5-tritiahexano (6.2 %), 1,2,4-tritiolano (1.1 %) y 2,4-ditiapentano (1.1 %). En relación con la actividad insecticida, el extracto de las flores mostró una gran actividad con CL99.9 de 0.032 mg/mL y CL99.9 de 0.969 mg/mL en larvas y pupas de A. aegypti, respectivamente, y la inhibición más alta de la enzima acetilcolinesterasa (0.00019 mg/mL) ex situ. El extracto de las flores presentó actividad anticolinesterasa y larvicida, 12.8 y 35.6 %, respectivamente, mayor que el control temephos. Conclusiones: Este estudio abre nuevas perspectivas sobre el uso de extractos de G. integrifolia como alternativa bioinsecticida para el control de larvas y pupas de A. aegypti.

Ginger essential oil and fractions against Mycobacterium spp.

ETHNOPHARMACOLOGICAL RELEVANCE: Zingiber officinale (ginger) is a perennial herbaceous plant native in tropical Asia and generally cultivated in most American tropical countries with widespread use in popular medicine. Ginger essential oil (GEO) has been reported to exhibit several biological activities, such as antimicrobial. AIMS OF THE STUDY: The aim of this study was to determine the composition and the property of GEO and related fractions against Mtb and NTM, as well as their cytotoxicity. METHODS AND MATERIALS: GEO was obtained by hydrodistillation and fractionation was performed. Chemical characterization of GEO and fractions were carried out by gas chromatography/mass spectrometry. The antimycobacterial activity was evaluated by resazurin microtiter assay plate and broth microdilution method for Mtb and NTM, respectively. The cytotoxicity in Vero cells was assessed by MTT colorimetric assay. RESULTS: The analyses showed 63 compounds in the GEO sample, characterized by a high number of monoterpenes and sesquiterpenes. GEO fractionation rendered 11 fractions (FR1 to FR11). GEO and fractions minimum inhibitory concentration ranged from 31.25 to >250 µg/mL against Mtb and from 15.6 to >250 µg/mL against NTM. GEO showed better activity against NTM, M. chelonae, and M. abscessus sub. massiliense, than the semi-pure fractions. One fraction (FR5), containing γ-eudesmol as the main compound, was the most active against Mtb and NTM. The GEO and semi-pure fractions cytotoxicity assay showed CC50 63.3 µg/mL, and 36.3-312.5 µg/mL, respectively. CONCLUSIONS: In general, GEO showed a mix of monoterpenes and sesquiterpenes and a better antimycobacterial activity than the semi-pure fractions. Cytotoxic effects of GEO and its fractions should be better investigated.