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dc.contributor.authorSantos, Carlos Henrique Corrêa dos
dc.date.accessioned2023-12-21T18:59:25Z-
dc.date.available2023-12-21T18:59:25Z-
dc.date.issued2018-10-19
dc.identifier.citationSANTOS, Carlos Henrique Corrêa dos. Metabólitos secundários e avaliação de atividades biológicas de Siolmatra brasiliensis (Cogn.) Baill. (Cucurbitaceae) e espécie do gênero Ziziphus Mill. (Rhamnaceae) - Vol.1. 2018. 211 f. Tese (Doutorado em Química) - Instituto de Química, Universidade Federal Rural do Rio de Janeiro, Seropédica, 2018.por
dc.identifier.urihttps://rima.ufrrj.br/jspui/handle/20.500.14407/10244-
dc.description.abstractVinte substâncias foram isoladas do extrato bruto hidroetanólico do caule de Siolmatra brasiliensis, suas estruturas foram determinadas por análises extensivas de RMN e EM-AR-ESI. Foram identificados cinco flavonoides, duas lignanas, um fitoesterol glicosilado e sete nor-cucurbitacinas já descritas na literatura além de um derivado fenólico e quatro saponinas de esqueleto do tipo damarano inéditas na literatura científica (siolmatrina e siolmatrosídeos II-V, respectivamente). Foram avaliadas as atividades antinociceptiva e anti-glicação in vitro do extrato bruto e frações da espécie. Sugere-se que a presença de saponinas do tipo damarano e nor-cucurbitacinas sejam responsáveis pela atividade antinociceptiva conferida ao extrato e especialmente fração em acetato de etila e que as substâncias fenólicas sejam responsáveis pela atividade anti-glicação conferida especialmente a fração em clorofórmio. Incluíram-se nesse trabalho quatro espécies do gênero Ziziphus para avaliação de atividades biológicas, onde Z. joazeiro e Z. glaziovii apresentaram resultados promissores de inibição bacteriana de Aliivibrio fischeri e Bacillus subtilis e todos os extratos apresentaram atividades citotóxicas significantes frente a linhagens celulares PC-3 e HT-29. Desessete substâncias foram isoladas da fração em clorofórmio do extrato metanólico do caule de Z. glaziovii, sendo uma xantona, uma lignana, dois triterpenos do tipo lupano, quatro do tipo ceanotano e um fitosterol glicosilado já descritos na literatura além de sete saponinas do tipo damarano inéditas na literatura científica (ziziglaziovigenina, ziziglaziovigenina 3-O-α-L-arabinopiranosídeo, ziziglaziovigenina-3-O-α-L-arabinofuranosil-(1-2)-α-L-arabinopiranosídeo, ziziglaziovigenina 3-O-β-D-glicopiranosil-(1-3)-α-L-arabinopiranosídeo, 16,22:16,30-diepóxi-20-hidróxidamar-24-metilideno 3-O-β-D-apiofuranosil-(1-3)-O-[6-(3-metóxi-4-hidróxibenzoato)-β-D-glicopiranosil-(1-2)]-β-D-glicopiranosil-(1-2)-β-D-glicopiranosídeo, 16,22-epóxi-15,16,20-trihidróxidamar-24-metilideno-3-O-β-D-apiofuranosil-(1-3)-O-[6-(3-metóxi-4-hidróxibenzoato)-β-D-glicopiranosil-(1-2)]-β-D-glicopiranosil-(1-2)-β-D-glicopiranosídeo e 16,22:16,30-diepóxi-20-hidróxidamar-24-metilideno 3-O-α-L-arabinofuranosil-(1-2)-O-[4-O-sódio-sulfato-β-D-glicopiranosil-(1-3)]-α-L-arabinopiranosídeo). As subtâncias foram avaliadas quanto à atividade antibacteriana, onde o ácido epigouânico e ácido alfitólico mostraram bons resultados frente a B. subtilis (IC50 de 20 e 12 µM, respectivamente). As substâncias apresentaram pouca ou nenhuma atividade citotóxica nas concentrações testadas (0,01 e 10 µM). A análise de CLUE-EM-EM da fração alcaloídica do extrato bruto do caule de Z. joazeiro possibilitou a identificação de oito alcaloides ciclopeptídicos do tipo Ib, onde as estruturas foram sugeridas por propostas de fragmentação de massas.por
dc.description.sponsorshipCAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superiorpor
dc.description.sponsorshipCNPq - Conselho Nacional de Desenvolvimento Científico e Tecnológicopor
dc.description.sponsorshipFAPERJ - Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiropor
dc.formatapplication/pdf*
dc.languageporpor
dc.publisherUniversidade Federal Rural do Rio de Janeiropor
dc.rightsAcesso Abertopor
dc.subjectSiolmatra brasiliensispor
dc.subjectZiziphuspor
dc.subjecttriterpenoidespor
dc.subjectalcaloides ciclopeptídicospor
dc.subjectatividades biológicaspor
dc.subjecttriterpenoidseng
dc.subjectcyclopeptide alkaloidseng
dc.subjectbiological activitieseng
dc.titleMetabólitos secundários e avaliação de atividades biológicas de Siolmatra brasiliensis (Cogn.) Baill. (Cucurbitaceae) e espécie do gênero Ziziphus Mill. (Rhamnaceae)por
dc.title.alternativeSecondary metabolites and evaluation of biological activities of Siolmatra brasiliensis (Cogn.) Baill. (Cucurbitaceae) and species from Ziziphus Mill. genus (Rhamnaceae)eng
dc.typeTesepor
dc.description.abstractOtherTwenty compounds were isolated from the crude hydroethanolic stem extract of Siolmatra brasiliensis, the structures were assigned by extensive NMR and HR-ESI-MS analyses. Five flavonoids, two lignans, one glycosylated phytosterol and seven nor-cucurbitacins already described in the literature were identified, along with a previously undescribed phenolic derivative and four dammarane-type saponins (siolmatrin and siolmatrosides II-V). The antinociceptive and in vitro antiglycation activities of the crude extract and fractions from the species were evaluated. It is suggested that the presence of dammarane-type saponins and nor-cucurbitacins are responsible for the observed antinociceptive activity of the extract and especially the ethyl acetate fraction, on the other hand, the identified phenolic compounds may be responsible for the anti-glycation activity observed specially in the chloroform fraction. Four species of Ziziphus were included in this project to evaluate biological activities, in which, Z. joazeiro and Z. glaziovii presented promising results of bacterial inhibition of Aliivibrio fischeri and Bacillus subtilis, and all extracts showed significant cytotoxic activities against PC- 3 and HT-29. Seventeen compounds were isolated from the chloroform fraction of Z. glaziovii stem extract, one xanthone, one lignan, two lupane-type triterpenes, four ceanothane-type triterpenes and one glycosylated phytosterol, besides seven previously undescribed dammarane-type saponins (ziziglaziovigenin, ziziglaziovigenin 3-O-α-L-arabinopyranoside, ziziglaziovigenin-3-O-α-L-arabinofuranosyl-(1-2)-α-L-arabinopyranoside, ziziglaziovigenin 3-O-β-D-glucopyranosyl-(1-3)-α-L-arabinopyranoside, 16,22:16,30-diepoxy-20-hydroxydammar-24-methylidene 3-O-β-D-apiofuranosyl-(1-3)-O-[6-(3-methoxy-4-hydroxybenzoate)-β-D-glucopyranosyl-(1-2)]-β-D-glucopyranosyl-(1-2)-β-D-glucopyranoside, 16,22-epoxy-15,16,20-trihydroxydammar-24-methylidene 3-O-β-D-apiofuranosyl-(1-3)-O-[6-(3-methoxy-4-hidroxybenzoate)-β-D-glucopyranosyl-(1-2)]-β-D-glucopyranosyl-(1-2)-β-D-glucopyranoside e 16,22:16,30-diepoxy-20-hydroxydammar-24-methylidene 3-O-α-L-arabinofuranosyl-(1-2)-O-[4-O-sodium-sulphate-β-D-glucopyranosyl-(1-3)]-α-L-arabinopyranoside. The compounds evaluated for antibacterial activity, where epigouanic acid and alphitolic acid showed good inhibition of B. subtilis (IC50 of 20 and 12 μM, respectively). The isolated compounds presented up to a 10 µM concentration, none or weak cytotoxic activity. UHPLC-MS-MS analysis of the alkaloidal fraction from the crude stem extract of Z. joazeiro stem allowed the identification of eight Ib-type cyclopeptide alkaloids, the structures were suggested by mass fragmentation proposals.eng
dc.contributor.advisor1Carvalho, Mario Geraldo de
dc.contributor.advisor1IDCPF: 257.152.327-91por
dc.contributor.advisor-co1Wessjohann, Ludger A.
dc.contributor.referee1Carvalho, Mario Geraldo de
dc.contributor.referee2Leitão, Gilda Guimarães
dc.contributor.referee3David, Jorge Maurício
dc.contributor.referee4Valverde, Alessandra Leda
dc.contributor.referee5Suzart, Luciano Ramos
dc.creator.IDCPF: 031.250.371-74por
dc.creator.Latteshttp://lattes.cnpq.br/9106363444050625por
dc.publisher.countryBrasilpor
dc.publisher.departmentInstituto de Químicapor
dc.publisher.initialsUFRRJpor
dc.publisher.programPrograma de Pós-Graduação em Químicapor
dc.relation.referencesAGRAWAL, P. K. Carbon-13 NMR of flavonoids. Studies in Organic Chemistry. v. 39, p. 95-182, 1989. AKIHISA, T.; HAYAKAWA, Y.; TOKUDA, H.; BANNO, N.; SHIMIZU, N.; SUZUKI, T.; KIMURA, Y. Cucurbitane Glycosides from the Fruits of Siraitia grosvenorii and their Inhibitory Effects on Epstein – Barr Virus Activation. Journal of Natural Products. v. 70, p. 783-788, 2007. ALGHASHAM, A. A. Cucurbitacins: A promising target for câncer therapy. International Journal of Health Sciences. v. 7, n. 1, p. 67-69, 2013. BALZA, F.; TOWERS, G. H. N. Dihydroflavonols of Artemisia dracunculus. Phytochemistry. v. 23 (10), p. 2333-2337, 1984. BARROSO, G. M. Sistemática de angiospermas do Brasil. Rio de Janeiro: Livros Técnicos e Científicos, 1978. v. 1. BARRERO, A. F.; HAÏDOUR, A.; DORADO, M. M.; GRAVALOS, D. G.; QUESADA, T. G. Lignans from the wood of Abies pinsapo. Journal of Natural Products. v. 57 (6), p. 713-719, 1994. BRUMMITT, R. K. Report of the Committee for Spermatophyta: 50. Taxon. v. 49 (4), p. 799-808, 2000. CHEN, J. C.; NIU, X. M.; LI, Z. R.; QIU, M. H. Four New Cucurbitane Glycosides from Hemsleya jinfushanensis. Planta Medica. v. 71, p. 983-986, 2005. CHEN, X. Q.; LI, Y.; HE, J.; WANG. K.; LI, M. M.; PAN, Z. H.; PENG, L. Y.; CHENG, X.; ZHAO, Q. S. Four New Lignans from Viburnum foetidum var. foetidum. Chemical and Pharmaceutical Bulletin. v. 57 (10), p. 1129-1131, 2009. CHOUNA, J. R.; NARDELLA, F.; LENTA, B. N.; VONTHRON-SÉNÉCHEAU, C.; NKENG-EFOUET-ALANGO, P.; SEWALD, N. Ceanothane-Type triterpenoids from Cyphostemma adenocaule. Archives of Pharmacal Research. p. 1-6, 2016. CYDZIK, M.; RUDOWSKA, M.; STEFANOWICZ, P.; SZEWCZUK, Z. The competition of charge remote and charge direct fragmentation mechanisms in quaternary ammonium salt derivatized peptides – an isotopic exchange study. Jounal of the American Society of Mass Spectrometry. v. 22 (12), p. 2103-2107, 2011. DAT, N. T.; JIN, X.; HONG, Y. S.; LEE, J. J. An Isoaurone and Other Constituents from Trichosanthes kirilowii Seeds Inhibit Hypoxia-Inductible Factor – 1 and Nuclear Factor – κB. Journal of Natural Products. v. 73, p. 1167-1169, 2010. DEVKOTA, H. P.; WATANABE, T.; YAHARA, S. Flavonoids and saponins from Zizyphus incurva. Natural Products Research. v. 27 (8), p. 697-701, 2013. DU, Q. & CUI, H. A new flavone glycoside from the fruits of Luffa cylindrical. Phytoterapia (Phytochemical communication). v. 78, p. 609-610, 2007. GAGNON, E.; BRUNEAU, A.; HUGHES, C. E.; de QUEIROZ, L. P.; LEWIS, G. P. A new generic system for the pantropical Caesalpinia group (Leguminosae). PhytoKeys. v. 71, pp. 1-160, 2016. GAIDI, G.; MAROUF, A.; HANQUET, B.; BAUER, R.; CORREIA, M.; CHAUFFERT, B.; LACAILLE-DUBOIS, M. A. A New Major Triterpene Saponin From the Roots of Cucurbita foetidissima. Journal of Natural Products. v. 63, p. 122-124, 2000. GIACCO, F.; BROWNLEE, M. Oxidative Stress and Diabetic Complications. Circulation Research. v. 107 (9), p. 1058-1070, 2010. GROVER, J. K.; YADAV, S. P. Pharmacological actions and potential uses of Momordica charantia: a review. Journal of Ethnopharmacology. v. 93, p. 123-132, 2004. HAN, J.; JI, C. J.; HE, W. J.; SHEN, Y.; LENG, Y.; XU, W. Y.; FAN, J. T.; ZENG, G. Z.; KONG, L. D.; TAN, N. H. Cyclopeptide Alkaloids from Ziziphus apetala. Journal of Natural Products. v. 74, p. 2571-2575, 2011. HAUENSCHILD, F.; MATUSZAK, S.; MUELLNER-RIEHL, A. N.; FAVRE, A. Phylogenetic relationships within the cosmopolitan buckthorn family (Rhamnaceae) support the resurrection of Sarcomphalus and the description of Pseudoziziphus gen. nov. Taxon. v. 65 (1), p. 47-64, 2016. HERNÁNDEZ-GALICIA, E.; CALZADA, F.; ROMAN-RAMOS, R.; ALARCÓNAGUILAR, F. Monoglycerides and Fatty acids from Ibervillea sonorea Root: Isolation and Hypoglicemic Activity. Planta medica. v. 73, p. 236-240, 2007. HIGUCHI, R.; KUBOTA, S.; KOMORI, T.; KAWASAKI, T.; PANDEY, V. B.; SINGH, J. P.; SHAH, A. H. Triterpenoid saponins from the bark of Zizyphus joazeiro. Phytochemistry. v. 23 (11), p. 2597-2600, 1984. HIMENO, E.; NAGAO, T.; HONDA, J.; OKABE, H.; IRINO, N.; NAKASUMI, T. Strucutures of Cayaponosides A, B, C and D, Glucosides of New nor-cucurbitacins in the Roots of Cayaponia tayuya. Chemical and Pharmaceutical Bulletin. v. 40 (10), p. 2885-2887, 1992. HIMENO, E.; NAGAO, T.; HONDA, J.; OKABE, H.; IRINO, N.; NAKASUMI, T. Strucutures of New Non-aromatized nor-cucurbitacin Glucosides in the Roots of Cayaponia tayuya. Chemical and Pharmaceutical Bulletin. v. 41 (5), p. 986-988, 1993. HUSSEIN, H. A.; ABDEL-HALIM, O. B.; MARWAN, E. S. M.; EL-GAMAL, A. A.; MOSANA, R. Dendocyn: an isocucurbitacin with novel cyclic side chain from Dendrosicyos socotrana. Phytochemistry. v. 65, p. 2551-2556, 2004. ITOH, T.; TSUKANE, M.; KOIKE, M.; NAKAMURA, C.; OHGUCHI, K.; ITO, M.; AKAO, Y.; KOSHIMIZU, S.; NOZAWA, Y.; WAKIMOTO, T.; NUKAYA, H.; SUWA, Y. Inhibitory Effects of Whisky Congeners on IgE-Mediated Degranulation in Rat Basophilic Leukemia RBL-2H3 Cells and Passive Cutaneous Anaphylaxis Reaction in Mice. Journal of Agricultural and Food Chemistry. v. 58, p. 7149-7157, 2010. JEFFREY, C. A new system of Cucurbitaceae. Botanicheskii Zhurnal. v. 90, p. 332- 335, 2005. JIMÉNEZ, C.; MARCOS, M.; VILLAVERDE, M. C.; RIQUERA, R.; CASTEDO, L.; STERMITZ, F. A Chromone from Zanthoxylum species. Phytochemistry. v. 28 (7), p. 1992- 1993, 1989. KALEEM, W. A., NISAR, M.; ZIA-UL-HAQ, M.; ADHIKARI, A.; DE FEO, V. New 14-Membered Cyclopeptide Alkaloids from Zizyphus oxyphylla Edgew. International Journal of Molecular Sciences. v. 13, p. 11520-11529, 2012. KALEEM, W. A.; NISAR. M..; KHAN, H.; RAUF, A. Pharmacological and Phytochemical Studies of Genus Zizyphus. Middle-East Journal of Scientific Research. v. 21 (8), p. 1243-1263, 2014. KANCHANAPOOM, T.; KASAI, R.; YAMASAKI, K. Cucurbitane, hexanorcucurbitane and octanorcucurbitane glycosides from fruits of Trichosanthes tricuspidata. Phytochemistry. v. 59, p. 215-228, 2002. KANG, K. B.; MING, G.; KIM, G. J.; HA, T-K-Q.; CHOI, H.; OH, W. K.; SUNG, S. H. Jubanines F-J, cyclopeptides alkaloids from the roots of Ziziphus jujuba. Phytochemistry. v. 119, p. 90-95, 2015. KANG, K. B.; KIM, J. W.; OH, W. K.; KIM, J.; SUNG, S. H. Cytotoxic Ceanothaneand Lupane-Type Triterpenoids from the Roots of Ziziphus jujuba. Journal of Natural Products. v. 79, p. 2364-2375, 2016a. KANG, K. B.; JANG, D. S.; KIM, J.; SUNG, S. H. UHPLC-ESI-qTOF-MS Analysis of Cyclopeptide Alkaloids in the seeds of Ziziphus jujuba var. spinosa. Mass Spectrometry Letters. v. 7 (2), p. 45-49, 2016b. KELLER, A. C.; MA, J.; KAVALIER, A.; HE, K.; BRILLANTES, A. M. B.; KENNELLY, E. J. Saponins from the traditional medicinal plant Momordica charantia stimulate insulin secretion in vitro. Phytomedicine. v. 19, p. 32-37, 2011. KOJIMA, H.; SATO, N.; HATANO, A.; OGURA, H. Sterol glucosides from Prunella vulgaris*. Phytochemstry. v. 29 (7), p. 2351-2355, 1990. KY, P. T.; HUONG, P. T.; MY, T. K.; ANH, P. T.; KIEM, P. V.; MINH, C. V.; CUONG, N. X.; THAO, N. P.; NHIEM, N. X.; HYUN, J. H.; KANG, H. K.; KIM, Y. H. Dammarane-Type Saponins from Gynostemma pentaphyllum. Phytochemistry. v. 71, p. 994- 1001, 2010. KURIHARA, Y.; OOKUBO, K.; TASAKI, H.; KODAMA, H.; AKIYAMA, Y.; YAGI, A.; HALPERN, B. Studies on taste modifiers. I. Purification and structure determination of sweetness inhibiting substances in leaves of Ziziphus jujuba. Tetrahedron. v. 44 (1), p. 61-66, 1988. LEAL, I. C. R.; SANTOS, K. R. N.; ITABAIANA Jr., I.; ANTUNES, O. A. C.; PORZEL, A.; WESSJOHANN, L.; KUSTER, R. M. Ceanothane and Lupane Type Triterpenes from Zizyphus joazeiro – An Anti-Staphylococcal Evaluation. Planta Medica. v. 76, p. 47-52, 2010. LEE, S. S.; SU, W. C.; LIU, K. C. S. C. Cyclopeptide Alkaloids from stems of Paliurus ramossisimus. Phytochemistry. v. 58, p. 1271-1276, 2001. LI, D.; CAO, J.; BI, X.; XIA, X.; LI, W.; ZHAO, Y. New dammarane-type triterpenoids from the leaves of Panax notoginseng and their protein tyrosine phosphatase 1B inhibitory activity. Journal of Ginseng Research. v. 38 (1), p. 28-33, 2014. LI, J.; WANG, R. F.; ZHOU, Y.; HU, H. J.; YANG, Y. B.; YANG, L.; WANG, Z. T. Dammarane-type triterpene oligoglycosides from the leaves and stems of Panax notoginseng and their anti-inflammatory activities. Journal of Ginseng Research. Disponível online, 2018. LI, W.; CAO, J.; TANG, Y.; ZHANG, L.; XIE, Q.; SHEN, H.; ZHAO, Y. Cyclic bisdesmosides from Actinostemma lobatum MAXIM (Cucurbitaceae) and their in vitro cytotoxicity. Fitoterapia. v. 83, p. 147-152, 2012. LI, X. C.; CAI, L.; WU, C. D. Antimicrobial compounds from Ceanothus americanus against oral pathogens. Phytochemistry. v. 46 (1), p. 97-102, 1997. LIMA, A. P.; BARBOSA, C. E. S.; PEREIRA, F.C.; VILANOVA-COSTA, C. A. S. T.; RIBEIRO, A. S. B. B.; SILVA, H. D.; AZEVEDO, N. R.; GOMES-KLEIN, V. L.; SILVEIRA-LACERDA, E. P. Siolmatra brasiliensis (Cogn.) Baill., Cucurbitaceae, acute toxicity in mice. Revista Brasileira de Farmacognosia. v. 20 (6), p. 917-921, 2010. LIMA, A. P.; PEREIRA, F. C.; VILANOVA-COSTA, C. A. S. T.; RIBEIRO, A. S. B. B. SILVEIRA-LACERDA, E. P. Avaliação da atividade antitumoral e citotóxica da planta Siolmatra brasiliensis. Revista eletrônica de Farmácia. v. 3, p. 44-46, 2006. LIMA, L. F. P. Estudos taxonômicos e morfopolínicos em Cucurbitaceae brasileira. Tese de doutorado (doutorado em botânica). Universidade Federal do Rio Grande do Sul - RS. 230p. 2010. LIMA, R. B. A família Rhamnaceae no Brasil, taxonomia e diversidade. Tese de Doutorado (Pós-graduação em Botânica). Universidade de São Paulo, São Paulo - SP. 292p. 2000. LIN, H. Y.; CHEN, C. H.; YOU, B. J.; LIU, K. C. S. C.; LEE, S. S. Cyclopeptide Alkaloids from Paliurus ramossisimus. Journal of Natural Products. v. 63, p. 1338-1343, 2000. LIU, W. Y; ZHANG, W. D.; CHEN, H. S.; GU, Z. B.; LI, T. Z.; CHEN, W. S. New triterpenoid saponins from bulbs of Bolbostemma paniculatum. Planta medica. v. 70, p 458- 464, 2004. LIU, X.; YE, W.; MO, Z.; YU, B.; ZHAO, S.; WU, H.; CHE, C.; JIANG, R.; MAK, T. C. W.; HSIAO, W. L. W. Five New Ocotillone-Type Saponins from Gynostemma pentaphyllum. Journal of Natural Products. v. 67, p. 1147-1151, 2004. MA, J.; WHITTAKER, P.; KELLER, A. C.; MAZZOLA, E. P.; PAWAR, R. S.; WHITE, K. D.; CALLAHAN, J. H.; KENNELLY, E. J.; KRYNITSKY, A. J.; RADER, J. I. Cucurbitane-type Triterpenoids from Momordica charantia. Planta medica. v. 76, p. 1758- 1761, 2010. MARKHAM, K. R. & TERNAI, B. 13C NMR of Flavonoids – II, Flavonoids other then flavone and flavonol aglycones. Tetrahedron. v. 32 (21), p. 2607-2612, 1976. MEEPROM, A.; SOMPONG, W.; CHAN, C. B.; ADISAKWATTANA, S. Isoferulic acid, a new anti-glycation agente, inhibits fructose- and glucose-mediated protein glycation in vitro. Molecules. v. 18 (6), p. 6439-6454, 2013. MOREJON, M. C.; LAUB, A.; KALUDEROVIĆ, G. N.; PUENTES, A. R.; HMEDAT, A. N.; OTERO-GONZALES, A. J.; RIVERA, D. G.; WESSJOHANN, L. A. A Multicomponent Macrocyclization Strategy to Natural Product-lyke Cyclic Peptides: Synthesis and Anticancer Evaluation of Surfactin and Mycosubtilin Analogues. Organic and Biomolecular Chemistry. v. 15, p. 3628-3637, 2017. MOTOMURA, K.; FUJIWARA, Y.; KIYOTA, N.; TSURUSHIMA, K.; TAKEYA, M.; NOHARA, T.; NAGAI, R.; IKEDA, T. Astragalosides Isolated from the Root as Astragalus Radix Inhibit the Formation of Advanced Glycation End Products. Journal of Agricultural and Food Chemistry. v. 57, p. 7666-7672, 2009. NORBERG, A.; HOA, N. K.; LIEPINSH, E.; PHAN, D. V.; THUAN, N. D.; JÖRNVALL, H.; SILLARD, R.; ÖSTENSON, C. G. A novel insulin-releasing substance, Phanoside, from the plant Gynostemma pentaphyllum. The Journal of biological Chemistry. v. 279 (40), p. 41361-41367, 2004. PANDEY, V. B.; DWIVEDI, S. P. D.; SHAH, A. H.; ECKHARDT, G. Nummularine- O, a cyclopeptide alkaloid from Zizyphus nummularia. Phytochemistry. v. 25 (11), p. 2690- 2691, 1986. PANSEETA, P.; LOMCHOEY, K.; PRABPAI, S.; KONGSAEREE, P.; SUKSAMRARN, A.; RUCHIRAWAT, S.; SUKSAMSARN, S. Antiplasmodial and antimycobacterial cyclopeptide alkaloids from the root of Ziziphus mauritiana. Phytochemistry. v. 72, p. 909-915, 2011. PETERS, R. R.; FARIAS, M. R.; RIBEIRO-DO-VALE, R. M. Anti-Inflammatory and Analgesic Effects of Cucurbitacins from Wilbrandia ebracteata. Planta Medica. v. 63, p. 525- 528, 1997. PLASTINA, P. Pharmacological Aspects of Jujubes. Pharmacologia. v. 7 (5), p. 243- 255, 2016. POGAM, P. L.; BOUSTIE, J. Xanthones of Lichen Source: A 2016 update. Molecules. v. 21 (2), p. 294-324, 2016. POTT, A & POTT V. J. Plantas do Pantanal. Brasília: Embrapa, 1994. 320p. RAMAN, A.; LAU, C. Anti-diabetic properties and phytochemistry of Momordica charantia L. (Cucurbitaceae). Phytomedicine. v. 2 (4), p. 349-362, 1996. RECIO, M. C.; PRIETO, M.; BONUCCELI, M.; ORSI, C.; MÁÑES, S.; GINER, R. M.; CERDÁ-NICOLÁS, M.; RÍOS, J. L. Anti-Inflammatory Activity of two Cucurbitacin Isolated from Cayaponia tayuya Roots. Planta Medica. v. 70, p. 414-420, 2004. RENAULT, J. H.; GHEDIRA, K.; THEPENIER, P.; LEVAUD, C.; ZECHESHANROT, M.; Le MEN-OLIVIER, L. Dammarane Saponins from Zizyphus lotus. Phytochemistry. v. 44 (7), p. 1321-1327, 1997. RICHARDSON, J. E.; FAY, M. F.; CRONK, Q. C. B.; BOWMAN, D.; CHASE, M. W. A phylogenetic analysis of Rhamnaceae using rbcL and trnL-F plastid DNA sequence. American Journal of Botany. v. 87 (9), p. 1309-1324, 2000. ROBINSON, G. L.; WUNDERLIN, R. P. Revision of SIOLMATRA (CUCURBITACEAE: ZANONIEAE). SIDA, Contributions to Botany. v. 21 (4), p. 1961- 1969, 2005. SANTOS, C. H. C.; BORGES, I. P.; SILVA, V. C.; SOUSA Jr., P. T.; KAWASHITA, N. H.; BAVIERA, A. M.; CARVALHO, M. G. A new dammarane saponin and other triterpenoids from Siolmatra brasiliensis and evaluation of the antidiabetic activity of its extract. Pharmaceutical Biology. v. 25, p. 1-9, 2016. SILVA, T. M. S.; CARVALHO, M. G.; BRAZ-FILHO, R. Estudo Espectroscópico em Elucidação Estrutural de Flavonóides de Solanum jabrense AGRA & NEE e S. paludosum MORIC. Química Nova. v. 32 (5), p. 1119-1128, 2009. SINGH, V. P.; BALI, A.; SINGH, N.; JAGGI, A. S. Advanced glycation end products and diabetic complications. Korean Journal of Physiology and Pharmacology. v. 18 (1), p. 1- 14, 2014. ŚLIWKA, L.; WIKTORSKA, K.; SUCHOCKI, P.; MILCZAREK, M.; MIELCZAREK, S.; LUBELSKA, K.; CIERPIAŁ, T.; ŁYŻWA, P.; KIEŁBASIŃSKI, P.; JAROMIN, A.; FLIS, A.; CHILMONCZYK, Z. The Comparison of MTT and CV Assays for the Assessment of Anticancer Agent Interactions. Plos One. v. 11 (5): e0155772, 2016. SOUZA, V. C.; LORENZI, H. Botânica sistemática: guia ilustrado para identificação das famílias de Angiospermas da flora brasileira, baseado em APG II. Nova Odessa: Instituto Plantarum, 2005. 640p. SU, D.; TANG, W.; HU, Y.; LIU, Y, YU, S.; MA, S.; QU, J.; YU, D. Lignan Glycosides from Neoalsomitra integrifoliola. Journal of Natural Products. v. 71, p. 784-788, 2008. SUKSAMRARN, S; PANSEETA, P.; KUNCHANAWATTA, S.; DISTAPORN, T.; RUKTASING, S.; SUKSAMRARN, A. Ceanothane- and Lupane-Type Triterpenes with Antiplasmodial and Antimycobaterial Activities from Ziziphus cambodiana. Chemical and Pharmaceutical Bulletin. v. 54 (4), p. 535-537, 2006. TSCHESCHE, R.; KHOKHAR, I.; WILHELM, H.; ECKHARDT, G. Jubanin-A und Jubanin-B, neue cyclopeptidalkaloide aus Ziziphus jujuba. Phytochemistry. v. 15 (4), 541- 542, 1976. TOMMASI, N.; DE SIMONE, F.; SPERANZA, G.; PIZZA, C. Studies on the Contituents of Cyclanthera pedate (Caigua) Seeds: Isolation and Characterization of Six New Cucurbitacin Glycosides. Journal of Agricultural and Food Chemistry. v. 44, p. 2020-2025, 1996. TSUNG-REN, Y.; KASAI, R.; ZHOU, J.; TANAKA, O. Dammarane saponins of leaves and seeds of Panax notoginseng. Phytochemistry. v. 22 (6), p. 1473-1478, 1983. UKIYA, M.; AKIHISA, T.; YASUKAWA, K.; TOKUDA, H.; TORIUMI, M.; KOIKE, K.; KIMURA, Y.; NIKAIDO, T.; AOI, W.; NISHINO, H.; TAKIDO, M.; Anti- Inflammatory and Anti-Tumor-Promoting Effects of Cucurbitane Glycosides from the Roots of Bryonia dioica. Journal of Natural Products. v. 65, p. 179-183, 2002. UR-RAHMAN, I.; KHAN, M. A.; ARFAN, M.; AKHTAR, G.; KHAN, L.; AHMAD, V. U. A new 14-membered cyclopeptide alkaloid from Zizyphus oxyphylla. Natural Products Research. v. 21 (3), p. 243-253, 2007. UR-RAHMAN, I.; KHAN, M. A.; KHAN, G. A.; KHAN, L.; AHMAD, V. U. Cyclopeptide Alkaloids of Zizyphus Species. Journal of the Chemical Society of Pakistan. v. 23 (4), p. 268-277, 2001. VALLI, M.; RUSSO, H. M.; BOLZANI, V. S. The potential contribution of the natural products from Brazilian biodiversity to bioeconomy. Anais da Academia Brasileira de Ciências. v. 90 (1), p. 763-778, 2018. VASCONCELOS, J. M. J.; SILVA, A. M. S.; CAVALEIRO, J. A. S. Chromones and Flavanones from Artemisia campestris Subsp. maritima. Phytochemistry. v. 49 (5), p. 1421- 1424, 1998. VIEGAS JR, C.; BOLZANI, V. S.; BARREIRO, E. J. Os produtos naturais e a química medicinal moderna. Química Nova. v. 29 (2), p. 326-337, 2006. VINSON, J. A.; HOWARD, T. B. Inhibition of protein glycation and advanced glycation end products by ascorbic acid and other vitamins and nutrients. Journal of Nutritional Biochemistry. v. 7, p. 659-663, 1996. WANG, D. C.; XIANG, H.; LI, D.; GAO, H. Y.; CAI, H.; WU, L. J.; DENG, X. M. Purine-containing cucurbitane triterpenoids from Cucurbita pepo cv dayangua. Phytochemistry. v. 69, p. 1434-1438, 2008. WANG, Y.; DING, B.; LUO, D.; CHEN, L. Y.; HOU, Y. L.; DAI, Y.; YAO, X. S. New triterpene glycosides from Ziziphi Spinosae Semen. Fitoterapia. v. 90, p. 185-191, 2013. YANG, R.; WANG, W. X.; CHEN, H. J.; HE, Z. C.; JIA, A. Q. The inhibition of advanced glycation end-products by five fractions and three main flavonoids from Camellia nitidissima Chi flowers. Journal of Agricultural and Food Chemistry. v. 57 (17), p. 7666- 7672, 2018. YANG, T. R.; KASAI, R.; ZHOU, J.; TANAKA, O. Dammarane saponins of leaves and seeds of Panax notoginseng. Phytochemistry. v. 22 (6), p. 1473-1478, 1983 YEH, W. J.; HSIA, S. M.; LEE, W. H.; WU, C. H. Plyphenols with antiglycation activity and mechanism of action: A review of recent findings. Journal of Food and Drug Analysis. v. 25, p. 84-92, 2017. YIN, F.; ZHANG, Y.; YANG, Z.; CHENG, Q.; HU, L. Triterpene Saponins from Gynostemma cardiospermum. Journal of Natural Products. v. 69 (10), p. 1394-1398, 2006. YOSHIKAWA, K.; SHIMONO, N.; ARIHARA, S. Antisweet Substances, Jujubasaponins I-III from Zizyphus jujuba, Revised Structure of Ziziphin. Tetrahedron Letters. v. 32 (48), p. 7059-7062, 1991. YOSHIKAWA, K; SHIMONO, N.; ARIHARA, S. Antisweet Natural Products. 1) Jujubasaponins IV, V and VI from Zizyphus jujuba Mill. Chemical and Pharmaceutical Bulletin. v. 40 (9), p. 2275-2278, 1992. YOSHIKAWA, M.; MURAKAMI, T.; UENO, T.; HIROKAWA, N.; YASHIRO, K.; MURAKAMI, N.; YAMAHARA, J.; MATSUDA, H.; SAIJOH, R.; TANAKA, O. Bioactive Saponins and Glycosides. IX1) Notoginseng (2): Structures of five New Dammarane-Type Triterpenes Oligoglycosides, Notoginsenosides-E, -G, -H, -I, and -J, and a Novel Acetylenic Fatty Acid Glycoside, Notoginsenic Acid β-Sophoroside, from the Dried Root of Panax notoginseng (Burk.) F. H. Chen. Chemical and Pharmaceutical Bulletin. v. 45 (6), p. 1056- 1062, 1997.por
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