Milton Groppo scite author profile

With contributions by: Abreu, Maria C.; Acevedo-Rodríguez, Pedro; Agra, Maria F.; Almeida Jr., Eduardo B.; Almeida, Gracineide S.S.; Almeida, Rafael F.; Alves, Flávio M.; Alves, Marccus; Alves-Araujo, Anderson; Amaral, Maria C.E.; Amorim, André M.; Amorim, Bruno; Andrade, Ivanilza M.; Andreata, Regina H.P.; Andrino, Caroline O.; Anunciação, Elisete A.; Aona, Lidyanne Y.S.; Aranguren, Yani; Aranha Filho, João L.M.; Araújo, Andrea O.; Araújo, Ariclenes A.M.; Araújo, Diogo; Arbo, María M.; Assis, Leandro; Assis, Marta C.; Assunção, Vivian A.; Athiê-Souza, Sarah M.; Azevedo, Cecilia O.; Baitello, João B.; Barberena, Felipe F.V.A.; Barbosa, Maria R.V.; Barros, Fábio; Barros, Lucas A.V.; Barros, Michel J.F.; Baumgratz, José F.A.; Bernacci, Luis C.; Berry, Paul E.; Bigio, Narcísio C.; Biral, Leonardo; Bittrich, Volker; Borges, Rafael A.X.; Bortoluzzi, Roseli L.C.; Bove, Cláudia P.; Bovini, Massimo G.; Braga, João M.A.; Braz, Denise M.; Bringel Jr., João B.A.; Bruniera, Carla P.; Buturi, Camila V.; Cabral, Elza; Cabral, Fernanda N.; Caddah, Mayara K.; Caires, Claudenir S.; Calazans, Luana S.B.; Calió, Maria F.; Camargo, Rodrigo A.; Campbell, Lisa; Canto-Dorow, Thais S.; Carauta, Jorge P.P. †; Cardiel, José M.; Cardoso, Domingos B.O.S.; Cardoso, Leandro J.T.; Carneiro, Camila R.; Carneiro, Cláudia E.; Carneiro-Torres, Daniela S.; Carrijo, Tatiana T.; Caruzo, Maria B.R.; Carvalho, Maria L.S.; Carvalho-Silva, Micheline; Castello, Ana C.D.; Cavalheiro, Larissa; Cervi, Armando C. †; Chacon, Roberta G.; Chautems, Alain; Chiavegatto, Berenice; Chukr, Nádia S.; Coelho, Alexa A.O.P.; Coelho, Marcus A.N.; Coelho, Rubens L.G.; Cordeiro, Inês; Cordula, Elizabeth; Cornejo, Xavier; Côrtes, Ana L.A.; Costa, Andrea F.; Costa, Fabiane N.; Costa, Jorge A.S.; Costa, Leila C.; Costa-e-Silva, Maria B.; Costa-Lima, James L.; Cota, Maria R.C.; Couto, Ricardo S.; Daly, Douglas C.; De Stefano, Rodrigo D.; De Toni, Karen; Dematteis, Massimiliano; Dettke, Greta A.; Di Maio, Fernando R.; Dórea, Marcos C.; Duarte, Marília C.; Dutilh, Julie H.A.; Dutra, Valquíria F.; Echternacht, Lívia; Eggers, Lilian; Esteves, Gerleni; Ezcurra, Cecilia; Falcão Junior, Marcus J.A.; Feres, Fabíola; Fernandes, José M.; Ferreira, D.M.C.; Ferreira, Fabrício M.; Ferreira, Gabriel E.; Ferreira, Priscila P.A.; Ferreira, Silvana C.; Ferrucci, Maria S.; Fiaschi, Pedro; Filgueiras, Tarciso S.; Firens, Marcela; Flores, Andreia S.; Forero, Enrique; Forster, Wellington; Fortuna-Perez, Ana P.; Fortunato, Reneé H.; Fraga, Cláudio N.; França, Flávio; Francener, Augusto; Freitas, Joelcio; Freitas, Maria F.; Fritsch, Peter W.; Furtado, Samyra G.; Gaglioti, André L.; Garcia, Flávia C.P.; Germano Filho, Pedro; Giacomin, Leandro; Gil, André S.B.; Giulietti, Ana M.; Godoy, Silvana A.P. ; Goldenberg, Renato; Gomes da Costa, Géssica A.; Gomes, Mário; Gomes-Klein, Vera L.; Gonçalves, Eduardo Gomes; Graham, Shirley; Groppo, Milton; Guedes. Juliana S.; Guimarães, Leonardo R.S.; Guimarães, Paulo J.F.; Guimarães, Elsie F.; Gutierrez, Raul; Harley, Raymond; Hassemer, Gus...

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Phylogeny of Rutaceae based on twononcoding regions from cpDNA

Groppo

Pirani

Salatino

et al. 2008

American J of Botany

144

166

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Primarily known only by the edible fruits of Citrus, Rutaceae comprise a large (c. 160 genera and 1900 species), morphologically diverse, cosmopolitan family. Of its extraordinary array of secondary chemical compounds, many have medicinal, antimicrobial, insecticidal, or herbicidal properties. To assist with the much-needed suprageneric reclassification and with studies of evolution of chemical compounds and biogeographic history of the family, here we included sequence data (from two noncoding regions of the chloroplast genome-rps16 intron and trnL-trnF region) from 65 species in 59 genera (more than one third of those in the family) that represented all subfamilies and tribes and more genera of Toddalioideae and of neotropical groups than previous studies. Results confirmed that Cneorum, Ptaeroxylon, Spathelia, and Dictyoloma form a clade sister to the remaining Rutaceae, none of the subfamilies with more than one genus (except Aurantioideae) is monophyletic, and characters of the ovary and fruit are not reliable for circumscription of subfamilies. Furthermore, clades are better correlated with geographic distributions of the genera than with ovary and fruit characters. Circumscriptions of subfamilies and tribes (and some subtribes of Rutoideae) must be reevaluated. Results are discussed in light of geographic distributions, caryology, chemotaxonomy, and other molecular studies.

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Antimicrobial Activity of Rosmarinus officinalis against Oral Pathogens: Relevance of Carnosic Acid and Carnosol

Bernardes

Lucarini

Tozatti

et al. 2010

Chemistry & Biodiversity

172

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The in vitro inhibitory activity of crude EtOH/H2O extracts from the leaves and stems of Rosmarinus officinalis L. was evaluated against the following microorganisms responsible for initiating dental caries: Streptococcus mutans, S. salivarius, S. sobrinus, S. mitis, S. sanguinis, and Enterococcus faecalis. Minimum inhibitory concentrations (MIC) were determined with the broth microdilution method. The bioassay-guided fractionation of the leaf extract, which displayed the higher antibacterial activity than the stem extract, led to the identification of carnosic acid (2) and carnosol (3) as the major compounds in the fraction displaying the highest activity, as identified by HPLC analysis. Rosmarinic acid (1), detected in another fraction, did not display any activity against the selected microorganisms. HPLC Analysis revealed the presence of low amounts of ursolic acid (4) and oleanolic acid (5) in the obtained fractions. The results suggest that the antimicrobial activity of the extract from the leaves of R. officinalis may be ascribed mainly to the action of 2 and 3.

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Phylogeny and biogeography of the pantropical genus Zanthoxylum and its closest relatives in the proto-Rutaceae group (Rutaceae)

Appelhans

Reichelt

Groppo

et al. 2018

Molecular Phylogenetics and Evolution

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Schistosomicidal Activity of the Essential Oil of Ageratum conyzoides L. (Asteraceae) against Adult Schistosoma mansoni Worms

et al. 2011

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The in vitro schistosomicidal effects of the essential oil of Ageratum conyzoides L. (Ac-EO) against adult worms of Schistosoma mansoni is reported in this paper. Concerning this activity, Ac-EO was considered to be active, but less effective than the positive control (praziquantel, PZQ) in terms of separation of coupled pairs, mortality, decrease in motor activity, and tegumental alterations. However, Ac-EO caused an interesting dose-dependent reduction in the number of eggs of S. mansoni. Precocene I (74.30%) and (E)-caryophyllene (14.23%) were identified as the two major constituents of Ac-EO. These compounds were tested individually and were found to be much less effective than Ac-EO and PZQ. A mixture of the two major compounds in a ratio similar to that found in the Ac-EO was also less effective than Ac-EO, thus revealing that there are no synergistic effects between these components. These results suggest that the essential oil of A. conyzoides is very promising for the development of new schistosomicidal agents.

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A new subfamily classification of the Citrus family (Rutaceae) based on six nuclear and plastid markers

Appelhans

Bayly

Heslewood

et al. 2021

TAXON

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Rutaceae is a family of angiosperms well known for the economically important genus Citrus. The division of Rutaceae into subfamilies is still inadequate and provisional. Previous phylogenetic studies at the family level are characterized by a limited sampling of genera and lack several crucial taxa. Here, we present a phylogenetic study based on six nuclear and plastid markers including 87.7% of the currently accepted genera, which is more than twice as many as in previous studies. Seven genera are included in a phylogenetic analysis for the first time. Most clades are resolved with high support, and we propose a new subfamily classification for Rutaceae that comprises the subfamilies Amyridoideae, Aurantioideae, Cneoroideae, Haplophylloideae, Rutoideae and Zanthoxyloideae. Aurantioideae is the only traditional subfamily that is resolved as monophyletic. We tested whether 13 morphological and karyological characters are taxonomically informative in Rutaceae. Chromosome numbers are clearly different in the two main clades of Rutaceae, but fruit characteristics, which have been used to define subfamilies in the past, do not distinguish between the main lineages of the family.

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Dalbergia ecastaphyllum (L.) Taub. and Symphonia globulifera L.f.: The Botanical Sources of Isoflavonoids and Benzophenones in Brazilian Red Propolis

et al. 2020

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The Brazilian red propolis (BRP) constitutes an important commercial asset for northeast Brazilian beekeepers. The role of Dalbergia ecastaphyllum (L.) Taub. (Fabaceae) as the main botanical source of this propolis has been previously confirmed. However, in addition to isoflavonoids and other phenolics, which are present in the resin of D. ecastaphyllum, samples of BRP are reported to contain substantial amounts of polyprenylated benzophenones, whose botanical source was unknown. Therefore, field surveys, phytochemical and chromatographic analyses were undertaken to confirm the botanical sources of the red propolis produced in apiaries located in Canavieiras, Bahia, Brazil. The results confirmed D. ecastaphyllum as the botanical source of liquiritigenin (1), isoliquiritigenin (2), formononetin (3), vestitol (4), neovestitol (5), medicarpin (6), and 7-O-neovestitol (7), while Symphonia globulifera L.f. (Clusiaceae) is herein reported for the first time as the botanical source of polyprenylated benzophenones, mainly guttiferone E (8) and oblongifolin B (9), as well as the triterpenoids β-amyrin (10) and glutinol (11). The chemotaxonomic and economic significance of the occurrence of polyprenylated benzophenones in red propolis is discussed.

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Chilean Pitavia more closely related to Oceania and Old World Rutaceae than to Neotropical groups: evidence from two cpDNA non-coding regions, with a new subfamilial classification of the family

Groppo¹,

Kallunki²,

Pirani³

et al. 2012

PHYTOKEYS

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The position of the plant genus Pitavia within an infrafamilial phylogeny of Rutaceae (rue, or orange family) was investigated with the use of two non-coding regions from cpDNA, the trnL-trnF region and the rps16 intron. The only species of the genus, Pitavia punctata Molina, is restricted to the temperate forests of the Coastal Cordillera of Central-Southern Chile and threatened by loss of habitat. The genus traditionally has been treated as part of tribe Zanthoxyleae (subfamily Rutoideae) where it constitutes the monogeneric tribe Pitaviinae. This tribe and genus are characterized by fruits of 1 to 4 fleshy drupelets, unlike the dehiscent fruits typical of the subfamily. Fifty-five taxa of Rutaceae, representing 53 genera (nearly one-third of those in the family) and all subfamilies, tribes, and almost all subtribes of the family were included. Parsimony and Bayesian inference were used to infer the phylogeny; six taxa of Meliaceae, Sapindaceae, and Simaroubaceae, all members of Sapindales, were also used as out-groups. Results from both analyses were congruent and showed Pitavia as sister to Flindersia and Lunasia, both genera with species scattered through Australia, Philippines, Moluccas, New Guinea and the Malayan region, and phylogenetically far from other Neotropical Rutaceae, such as the Galipeinae (Galipeeae, Rutoideae) and Pteleinae (Toddalieae, former Toddalioideae). Additionally, a new circumscription of the subfamilies of Rutaceae is presented and discussed. Only two subfamilies (both monophyletic) are recognized: Cneoroideae (including Dictyolomatoideae, Spathelioideae, Cneoraceae, and Ptaeroxylaceae) and Rutoideae (including not only traditional Rutoideae but also Aurantioideae, Flindersioideae, and Toddalioideae). As a consequence, Aurantioideae (Citrus and allies) is reduced to tribal rank as Aurantieae.

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Milton Groppo

Growing knowledge: an overview of Seed Plant diversity in Brazil

Phylogeny of Rutaceae based on twononcoding regions from cpDNA

Antimicrobial Activity of Rosmarinus officinalis against Oral Pathogens: Relevance of Carnosic Acid and Carnosol

Phylogeny and biogeography of the pantropical genus Zanthoxylum and its closest relatives in the proto-Rutaceae group (Rutaceae)

Schistosomicidal Activity of the Essential Oil of Ageratum conyzoides L. (Asteraceae) against Adult Schistosoma mansoni Worms

A new subfamily classification of the Citrus family (Rutaceae) based on six nuclear and plastid markers

Dalbergia ecastaphyllum (L.) Taub. and Symphonia globulifera L.f.: The Botanical Sources of Isoflavonoids and Benzophenones in Brazilian Red Propolis

Chilean Pitavia more closely related to Oceania and Old World Rutaceae than to Neotropical groups: evidence from two cpDNA non-coding regions, with a new subfamilial classification of the family

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