Chemical constituents of apolar fractions from fruit latex of twelve Clusia species (Clusiaceae)

CAMARA, CLAUDIO A.G. DA; MARSAIOLI, ANITA J.; BITTRICH, VOLKER

doi:10.1590/0001-3765201820170257

Abstract

The apolar fractions components of fruit latex of twelve species of Clusia belonging to four different taxonomic sections were examined by GC-MS. The latex of Clusia is characterised by large amounts of sesquiterpene hydrocarbons as major constituents like germacrene D: C. paralicola (44.28 %), C. criuva subsp. criuva (29.03 %); β-caryophyllene: C. fluminensis (35.61 %), C. lanceolata (36.39 %), C. hilariana (58.10 %); α-trans-bergamontene: C. spirictus-sanctensis (36.30 %); α-bulnesene: C. weddelliana (25.61 %); bicyclogermacrene: C. panapanari (25.93 %) and trans-β-farnesene: C. nemorosa (24.63 %), while C. grandiflora is composed of 42.16 % monoterpene hydrocarbons. Verbenone (31.91 %) was the major component. In contrast, C. rosea, C. grandiflora, C. lanceolata and C. criuva subsp. parviflora are rich in 3-methylcyclohexanone (19.56 %), hexadecanol (22.72 %), p-anisaldehyde (23.39 %) and octadecanol (26.81 %), respectively. This study suggests considerable chemical variation among the non-polar fractions of fruit latex of the twelve Clusia species.

Key words
Clusia spp; latex; apolar fraction; β-caryophyllene; verbenone

INTRODUCTION

Many plants can store a great diversity of liquids and fluids, including latex, resins, mucilage and gums in specialised cells, channels and/or intercellular cavities. The latex can be defined as a water-based suspension or emulsion of various types of small particles. Latex is accumulated either in living cells and/or specialised structures called laticifers (Lewinsohn 1991LEWINSOHN TM. 1991. The geographical distribution of plant latex. Chemoecology 2: 64-68.) or in intercellular secretory canals or ducts lined by epithelial cells secreting substances into the canal. The latter is the case in the close families Clusiaceae, Calophyllaceae and Hypericaceae (Vismia). The aqueous suspension is generally constituted by an infinity of compounds belonging to a variety of classes, including inorganic constituents. Among the secondary compounds present in these suspensions, mainly terpenoids, fatty acids, aromatic compounds, hydrocarbons and alkaloids are found (Konno 2011KONNO K. 2011. Plant latex and other exudates as plant defense systems: roles of various defense chemicals and proteins contained therein. Phytochemistry 72: 1510-1530., Hua et al. 2015HUA J, LIU YC, JING SX, LUO SH and LI SH. 2015. Macrocyclic diterpenoids from the latex of Euphorbia helioscopia. Nat Prod Commun 10: 2037-2039.).

The roles of laticifers or secretory canals and latex in plants are up to now not completely clear, but it is generally assumed that they serve to store nutrients or that the latex has a distribution function for these nutrients for the different plant parts (Agrawal and Konno 2009AGRAWAL AA and KONNO K. 2009. Latex: a model for understanding mechanisms, ecology, and evolution of plant defense against herbivory. Annu Rev Ecol Syst 40: 311-331.). Other functions described for latex production units are regulation of water storage and oxygen transport in plants, and especially the protection of the plant against natural enemies, more precisely, microorganisms and herbivores (Hua et al. 2017HUA J, LIU Y, XIAO CJ, JING SX, LUO SH and LI SH. 2017. Chemical profile and defensive function of the latex of Euphorbia peplus. Phytochemistry 136: 56-64.). Comparison between closely related plant groups led to the hypothesis that the presence of latex is directly related to plant survival and species richness of clades (Farrell et al. 1991FARRELL BD, DUSSOURD DE AND MITTER C. 1991. Escalation of plant defense: do latex and resin canals spur plant diversification? Amer Naturalist 138: 881-900.). As plants with latex are observed with a higher frequency in Eudicotyledoneae, one estimates that about 40 families and more than 20,000 species are latex or resin producers (Konno 2011KONNO K. 2011. Plant latex and other exudates as plant defense systems: roles of various defense chemicals and proteins contained therein. Phytochemistry 72: 1510-1530.). Of these species, among the most important are the ones of the family Clusiaceae that can store in the latex and in the floral resin different classes of secondary compounds.

The neotropical genus Clusia L. (Clusiaceae) has attracted the interest of botanists for its resin producing flowers, which are collected especially by Euglossinia and Trigonini bees. Chemical research revealed that these resins are mainly composed of polyisoprenylated benzophenones (Porto et al. 2000PORTO ALM, MACHADO SMF, OLIVEIRA CMA, BITTRICH V, AMARAL MCE and MARSAIOLI AJ. 2000. Polyisoprenylated benzophenones from Clusia floral resins. Phytochemistry 55: 755-768., Anholeti et al. 2015ANHOLETI MC, PAIVA SR, FIGUEIREDO MR and KAPLAN MAC. 2015. Chemosystematic aspects of polyisoprenylated benzophenones from the genus Clusia. An Acad Bras Cienc 87: 289-301.) and have shown HIV-inhibitory activity (Wu et al. 2014WU SB, LONG C and KENNELLY EJ. 2014. Structural diversity and bioactivities of natural benzophenones. Nat Prod Rep 31: 1158-1174.).

Like all members of the family Clusiaceae, Clusia plants have latex in nearly all their tissues. Quantities and colour of the latex vary among the species but also between different plant organs of one plant. The latex, extracted mainly from fruits of the Clusia species has been used in popular medicine by ingestion for rheumatic treatment (Sanz-Biset et al. 2009SANZ-BISET J, CRUZ JC, RIVERA MAE and CAÑIGUERAL S. 2009. A first survey on the medicinal plants of the Chazuta valley (peruvian Amazon). J Ethnopharmacol 122: 333-362.) and infant oral candidiasis (Barbosa and Pinto 2003BARBOSA WLR and PINTO LN. 2003. Documentação e valorização da fitoterapia tradicional Kayapó nas aldeias A’Ukre e Pykanu - Sudeste do Pará. Rev Bra Farmacogn 13: 47-49.). Up to the present moment, only one study referring to the chemical composition of latex from Clusia has been realized, which was restricted to C. grandiflora species where the antimicrobial activity of two polyisoprenylated benzophenones obtained from the latex of stems was reported (Lokvam et al. 2000LOKVAM J, BRADDOCK JF, REICHARDT PB and CLAUSEN TP. 2000. Two polyisoprenylated benzophenones from the trunk latex of Clusia grandiflora (Clusiaceae). Phytochemistry 55: 29-34.).

The present work has the objective to investigate the chemical composition of the apolar fraction of latex from fruits of twelve Clusia species pertinent to four sections (Chlamydoclusia, Criuva, Phloianthera and Cordylandra).

MATERIALS AND METHODS

COLLECTION OF PLANT MATERIAL

The latex were obtained from fruits of Clusia species cultivated on the “Fazenda Santa Elisa”, Agronomic Institute of Campinas (IAC), Campinas - SP, Brazil. Maria do Carmo Estanislau do Amaral and Volker Bittrich have deposited voucher specimens in the Herbarium of the State University of Campinas (UEC). The latter was responsible for the identifications. The species studied and herbarium numbers are listed in Table I.

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TABLE I
Herbarium number, colour and percentage of fruits latex from Clusia species collected in the Fazenda Santa Elisa of the Agronomic Institute of Campinas - SP, Brazil.

EXTRACTION OF LATEX

The exuded latex of plants was obtained from freshly cut fruits and collected onto methanol. Filtration and solvent evaporation produced methanolic extract. The triplicated yields were average and calculated based on fresh weight of the fruit. The fruits from different Clusia species were collected randomly.

ISOLATION OF APOLAR COMPONENT

Methanolic extract was dissolved in dichloromethane (30 mL) and filtrated on 2.0 g of silica gel 60 on glass column (Ø = 1 cm). The collected dichloromethane fraction was dried over anhydrous sodium sulphate and reduced to ca. 0.5 mL at room temperature under reduced pressure on a rotatory evaporator and stored in sealed vials at low temperature before analysis. Three replicated analyses were used for some species (C. paralicola, C. fluminensis, C. lanceolata, C. criuva subsp. parviflora, C. grandiflora, and C. rosea).

GAS CHROMATOGRAPHY FID (GC-FID) AND GAS CHROMATOGRAPHY-MASS SPECTROMETRY (GC-MS) ANALYSIS

Analyses were carried out using a HP-5990/5970 system equipped with a flame ionization detector (FID) and J&W Scientific non-polar DB-5 fused silica capillary column (30 m x 0.25 mm x 0.25 µm); column temperatures were programmed from 60 to 240 °C at 3 °C min-¹ for integrating purposes.

GC-FID ANALYSIS

Injector and detector temperatures were 220 and 285 °C respectively. Hydrogen was used as carrier gas at a flow rate 1.16 ml min-¹ in the split mode (1:30), with an injection volume, 1.0 µL solution of about 10 mg of latex in 1mL of dichloromethane. The amount of each compound was calculated from GC peak areas in the order of DB-5 column elution and expressed as a relative percentage of the total area of the chromatograms. The retention indices were obtained by co-injecting the oil sample with a C₁₁-C₂₄ linear hydrocarbon mixture (retention index from 900 to 1099 range was obtained by extrapolation).

GC-MS ANALYSIS

The carrier gas was helium and the temperature program was the same as that for GC experiments. The mass spectra were taken at 70 eV with a scanning speed of 0.84 scan s-¹ from m/z 40 to 550.

The latex were analysed by GC and GC-MS, and identification was made on the basis of standard compound co-injection and comparison of retention indices (Van den Dool and Kratz 1963VAN DEN DOOL and KRATZ PD. 1963. A generalization of the retention index system including linear temperature programmed gas liquid partition chromatography. J Chromatogr A 11: 463-471.) as well as by computerised matching of the acquired mass spectra with those stored in wiley / NBS mass spectral library of the GC-MS data system and other published mass spectra (Adams 2007ADAMS RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Quadrupole Mass Espectroscopy, 4th ed., Carol Stream: Allured Publishing Corporation, 804 p.).

RESULTS AND DISCUSSION

The latex isolated from the fruits of different Clusia species showed colours from white to yellowish green with characteristic citric odours. The yields (calculated based on fresh fruits weight) of fruits latex of Clusia species are shown in Table I as well as the colour and herbarium number.

This investigation allowed the identification of more than 70 components in the dichloromethane fractions of the late latexes from different Clusia species. In the mean 15 compounds were identified in each species, which are represented in more than 99 % of the fruits latex. In general, even species with the same taxonomic section, showed different composition of the dichloromethane fraction of the latex. With the objective of getting a better visualization of the molecules comprising the apolar latex constituents of the fruits from the different studied species, the identified compounds were allocated in three different compound groups in accordance with the criteria established by Knudsen et al. (1993)KNUDSEN JT, TOLLSTEN L and BERGSTRÖM LG. 1993. Floral scents - a checklist of volatile compounds isolated by head-space techniques. Phytochemistry 33: 253-280., which are fatty acid derivatives, isoprenoids and benzenoids (Table II).

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TABLE II
Percentage of chemical constituents of apolar fractions from fruits latex of twelve Clusia species belonging to four taxonomic sections.

Curiously, the five benzenoid compounds identified (benzaldehyde, acetophenone, methyl benzoate, ethyl benzoate and p-anisaldehyde), were never found simultaneously in the investigated species. Nevertheless, comparison of the latex composition of these Clusia species shows that, although not being the compound class with the major quantity, benzenoid compounds are characterised (quantity > 0.1 %) in practically all species, with exception of C. panapanari and C. spirictu-sanctensis of the section Cordylandra (Table II). The benzenoid compounds present at more than 1 % concentration were acetophenone, section Cordylandra (C. weddelliana, 3.83 %), section Chlamydoclusia (C. rosea, 10.49 %), section Criuva (C. criuva subsp. parviflora, 3.11 % and C. criuva subsp. criuva, 2.73 %); ethyl benzoate, only present in section Criuva (C. criuva subsp. parviflora, 4.53 % and C. criuva subsp. criuva, 2.34) and p-anisaldehyde, in Chlamydoclusia section (C. grandiflora, 1.21 %), Section Criuva (C. criuva subsp. criuva, 1.11 %) and section Phloianthera (C. lanceolata, 23.39 %). Aromatic esters, aromatic aldehydes, aromatic ketone and fatty acid derivatives have been reported to be part of floral scents for Clusia species. However, with the exception of acetophenone, ethyl benzoate, methyl benzoate, p-anisaldehyde and benzaldehyde, found in apolar fractions of fruits latex were also identified in the floral essential oil from the same Clusia species here investigated (Nogueira et al. 2001NOGUEIRA PC, BITTRICH V, SHEPHERD GJ, LOPES AV and MARSAIOLI AJ. 2001. The ecological taxonomic importance of flower volatiles of Clusia species (Guttiferae). Phytochemistry 56: 443-452.).

By the organisation of the latex constituents in the above-mentioned three groups, independently from taxonomic section, the predominance of compounds from the isoprenoid class became evident. Outstanding are the species of section Cordylandra, where isoprenoid concentration of 91.73 - 99.19 % were found. In the sections Chlamydoclusia and Phloianthera, only the species C. nemorosa (99.43 %) and C. hilariana (96.92 %) show isoprenoid percentages higher than 90 %. The other species show the respective value in the range of 47.50 - 82.53 %. With exception of C. grandiflora, which is comprised by 42.16 % monoterpene hydrocarbons with verbenone (31.91 %) as major component, C. rosea and C. criuva subsp. parviflora with 3-methylcyclohexanone (19.56 %) and octadecanol (26.81 %) as major constituents, all the other species are characterised by the presence of sesquiterpenes as major components. For example, in C. paralicola (44.28 %) and C. criuva subsp. criuva (29.03 %), the germacrene D is more abundant. Other sesquiterpenes that were present in high amounts were β-caryophyllene in C. fluminensis (35.61 %), C lanceolata (36.39 %) and C. hilariana (58.1 %); α-trans-bergamontene in C. spirictus-sanctensis (36.30 %); α-bulnesene in C. weddelliana (25.61 %); bicyclogermancrene in C. panapanari (25.93 %) and trans-β-farnesene in C. nemorosa (24.63 %) (Table II).

The main constituents of latex present in the different Clusia species were monoterpenes and sesquiterpenes and as the major percentile was observed verbenone (31.91 %) in C. grandiflora and β-caryophyllene (58.11 %) in C. hilariana. In relation to β-caryophyllene as a major constituent of apolar fraction of species from section Phloianthera, these findings are consistent with those reported by Guimarães et al. (2013)GUIMARÃES ALA, BIZARRI CHB, BARBOSA LS, NAKAMURA MJ, RAMOS MFS and VIEIRA ACM. 2013. Characterisation of the effects of leaf galls of Clusiamyia nitida (Cecidomyiidae) on Clusia lanceolata Cambess. (Clusiaceae): Anatomical aspects and chemical analysis of essential oil. Flora 208: 165-173. for the major constituent of essential oil from leaves of Clusia lanceolata (43.20 - 56.40 %) and by Fernandes et al. (2016)FERNANDES CP, CRUZ RAS, AMARAL RR, CARVALHO JCT, SANTOS MG, TIETBOHL LAC and ROCHA L. 2016. Essential oils from male and female flowers of Clusia hilariana. Chem Nat Compd 52: 1110-1112. for essential oil of flowers of Clusia hilariana (37.1 - 49.0 %), who found β-caryophyllene also as major constituent.

The constituents of the apolar fraction of fruit latex of Clusia species have been investigated for the first time and showed in all species, independent of the taxonomic section, the presence of fatty acid derivatives, benzenoids and isoprenoids. Our study shows qualitative and quantitative differences in the chemical compositions for the studied Clusia species, even between species belonging to the same taxonomic group. As an explanation, one can exclude differences in the habitat as all plants, from which the fruits were collected, are cultivated in the same small area of Fazenda Sta. Elisa in Campinas, São Paulo state. Thus, a genetic basis of the chemical differences must be assumed. Only in few cases, the chemical data show correlation with phylogenetic relationship of the studied species as supported by morphological and DNA sequence data (Gustafsson et al. 2007GUSTAFSSON MHG, BITTRICH V and WINTER K. 2007. Diversity, phylogeny and classification of Clusia. In: Lüttge U (Ed), Clusia: a woody Neotropical genus of remarkable plasticity and diversity. Ecological Studies, Heidelberg: Springer 194: 95-116.). There are no data yet about differences in the latex chemistry within the same species and the possibility of an infraspecific variation cannot be excluded. It seems plausible that the latex a least partly serves to protect the developing seeds from herbivores, until the fruits (still carnose) open to expose the seeds to birds for dispersal. The very dense canals in the pericarp support this idea. However, the specific role of the observed latex constituents in such a supposed protection is unknown, and thus the efficiency of the different components to deter possible attacks. Nevertheless, during many visits to the plants cultivated in Campinas, we never observed immature fruits damaged by herbivores; apparently, the chemical defense is efficient.

ACKNOWLEGMENTS

The authors are indebted to Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) for scholarship; Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP); Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) for financial support and Instituto Agronômico de Campinas (IAC) for the permission to collect fruits from plants cultivated on Fazenda Sta. Elisa.

REFERENCES

ADAMS RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Quadrupole Mass Espectroscopy, 4th ed., Carol Stream: Allured Publishing Corporation, 804 p.
AGRAWAL AA and KONNO K. 2009. Latex: a model for understanding mechanisms, ecology, and evolution of plant defense against herbivory. Annu Rev Ecol Syst 40: 311-331.
ANHOLETI MC, PAIVA SR, FIGUEIREDO MR and KAPLAN MAC. 2015. Chemosystematic aspects of polyisoprenylated benzophenones from the genus Clusia. An Acad Bras Cienc 87: 289-301.
BARBOSA WLR and PINTO LN. 2003. Documentação e valorização da fitoterapia tradicional Kayapó nas aldeias A’Ukre e Pykanu - Sudeste do Pará. Rev Bra Farmacogn 13: 47-49.
FARRELL BD, DUSSOURD DE AND MITTER C. 1991. Escalation of plant defense: do latex and resin canals spur plant diversification? Amer Naturalist 138: 881-900.
FERNANDES CP, CRUZ RAS, AMARAL RR, CARVALHO JCT, SANTOS MG, TIETBOHL LAC and ROCHA L. 2016. Essential oils from male and female flowers of Clusia hilariana. Chem Nat Compd 52: 1110-1112.
GUIMARÃES ALA, BIZARRI CHB, BARBOSA LS, NAKAMURA MJ, RAMOS MFS and VIEIRA ACM. 2013. Characterisation of the effects of leaf galls of Clusiamyia nitida (Cecidomyiidae) on Clusia lanceolata Cambess. (Clusiaceae): Anatomical aspects and chemical analysis of essential oil. Flora 208: 165-173.
GUSTAFSSON MHG, BITTRICH V and WINTER K. 2007. Diversity, phylogeny and classification of Clusia. In: Lüttge U (Ed), Clusia: a woody Neotropical genus of remarkable plasticity and diversity. Ecological Studies, Heidelberg: Springer 194: 95-116.
HUA J, LIU YC, JING SX, LUO SH and LI SH. 2015. Macrocyclic diterpenoids from the latex of Euphorbia helioscopia. Nat Prod Commun 10: 2037-2039.
HUA J, LIU Y, XIAO CJ, JING SX, LUO SH and LI SH. 2017. Chemical profile and defensive function of the latex of Euphorbia peplus. Phytochemistry 136: 56-64.
KNUDSEN JT, TOLLSTEN L and BERGSTRÖM LG. 1993. Floral scents - a checklist of volatile compounds isolated by head-space techniques. Phytochemistry 33: 253-280.
KONNO K. 2011. Plant latex and other exudates as plant defense systems: roles of various defense chemicals and proteins contained therein. Phytochemistry 72: 1510-1530.
LEWINSOHN TM. 1991. The geographical distribution of plant latex. Chemoecology 2: 64-68.
LOKVAM J, BRADDOCK JF, REICHARDT PB and CLAUSEN TP. 2000. Two polyisoprenylated benzophenones from the trunk latex of Clusia grandiflora (Clusiaceae). Phytochemistry 55: 29-34.
NOGUEIRA PC, BITTRICH V, SHEPHERD GJ, LOPES AV and MARSAIOLI AJ. 2001. The ecological taxonomic importance of flower volatiles of Clusia species (Guttiferae). Phytochemistry 56: 443-452.
PORTO ALM, MACHADO SMF, OLIVEIRA CMA, BITTRICH V, AMARAL MCE and MARSAIOLI AJ. 2000. Polyisoprenylated benzophenones from Clusia floral resins. Phytochemistry 55: 755-768.
SANZ-BISET J, CRUZ JC, RIVERA MAE and CAÑIGUERAL S. 2009. A first survey on the medicinal plants of the Chazuta valley (peruvian Amazon). J Ethnopharmacol 122: 333-362.
VAN DEN DOOL and KRATZ PD. 1963. A generalization of the retention index system including linear temperature programmed gas liquid partition chromatography. J Chromatogr A 11: 463-471.
WU SB, LONG C and KENNELLY EJ. 2014. Structural diversity and bioactivities of natural benzophenones. Nat Prod Rep 31: 1158-1174.

Publication Dates

Publication in this collection
Aug 2018

History

Received
4 Apr 2017
Accepted
4 July 2017

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ADAMS RP. 2007. Identification of Essential Oil Components by Gas Chromatography/Quadrupole Mass Espectroscopy, 4th ed., Carol Stream: Allured Publishing Corporation, 804 p.

[2] AGRAWAL AA and KONNO K. 2009. Latex: a model for understanding mechanisms, ecology, and evolution of plant defense against herbivory. Annu Rev Ecol Syst 40: 311-331.

[3] ANHOLETI MC, PAIVA SR, FIGUEIREDO MR and KAPLAN MAC. 2015. Chemosystematic aspects of polyisoprenylated benzophenones from the genus Clusia. An Acad Bras Cienc 87: 289-301.

[4] BARBOSA WLR and PINTO LN. 2003. Documentação e valorização da fitoterapia tradicional Kayapó nas aldeias A’Ukre e Pykanu - Sudeste do Pará. Rev Bra Farmacogn 13: 47-49.

[5] FARRELL BD, DUSSOURD DE AND MITTER C. 1991. Escalation of plant defense: do latex and resin canals spur plant diversification? Amer Naturalist 138: 881-900.

[6] FERNANDES CP, CRUZ RAS, AMARAL RR, CARVALHO JCT, SANTOS MG, TIETBOHL LAC and ROCHA L. 2016. Essential oils from male and female flowers of Clusia hilariana. Chem Nat Compd 52: 1110-1112.

[7] GUIMARÃES ALA, BIZARRI CHB, BARBOSA LS, NAKAMURA MJ, RAMOS MFS and VIEIRA ACM. 2013. Characterisation of the effects of leaf galls of Clusiamyia nitida (Cecidomyiidae) on Clusia lanceolata Cambess. (Clusiaceae): Anatomical aspects and chemical analysis of essential oil. Flora 208: 165-173.

[8] GUSTAFSSON MHG, BITTRICH V and WINTER K. 2007. Diversity, phylogeny and classification of Clusia. In: Lüttge U (Ed), Clusia: a woody Neotropical genus of remarkable plasticity and diversity. Ecological Studies, Heidelberg: Springer 194: 95-116.

[9] HUA J, LIU YC, JING SX, LUO SH and LI SH. 2015. Macrocyclic diterpenoids from the latex of Euphorbia helioscopia. Nat Prod Commun 10: 2037-2039.

[10] HUA J, LIU Y, XIAO CJ, JING SX, LUO SH and LI SH. 2017. Chemical profile and defensive function of the latex of Euphorbia peplus. Phytochemistry 136: 56-64.

[11] KNUDSEN JT, TOLLSTEN L and BERGSTRÖM LG. 1993. Floral scents - a checklist of volatile compounds isolated by head-space techniques. Phytochemistry 33: 253-280.

[12] KONNO K. 2011. Plant latex and other exudates as plant defense systems: roles of various defense chemicals and proteins contained therein. Phytochemistry 72: 1510-1530.

[13] LEWINSOHN TM. 1991. The geographical distribution of plant latex. Chemoecology 2: 64-68.

[14] LOKVAM J, BRADDOCK JF, REICHARDT PB and CLAUSEN TP. 2000. Two polyisoprenylated benzophenones from the trunk latex of Clusia grandiflora (Clusiaceae). Phytochemistry 55: 29-34.

[15] NOGUEIRA PC, BITTRICH V, SHEPHERD GJ, LOPES AV and MARSAIOLI AJ. 2001. The ecological taxonomic importance of flower volatiles of Clusia species (Guttiferae). Phytochemistry 56: 443-452.

[16] PORTO ALM, MACHADO SMF, OLIVEIRA CMA, BITTRICH V, AMARAL MCE and MARSAIOLI AJ. 2000. Polyisoprenylated benzophenones from Clusia floral resins. Phytochemistry 55: 755-768.

[17] SANZ-BISET J, CRUZ JC, RIVERA MAE and CAÑIGUERAL S. 2009. A first survey on the medicinal plants of the Chazuta valley (peruvian Amazon). J Ethnopharmacol 122: 333-362.

[18] VAN DEN DOOL and KRATZ PD. 1963. A generalization of the retention index system including linear temperature programmed gas liquid partition chromatography. J Chromatogr A 11: 463-471.

[19] WU SB, LONG C and KENNELLY EJ. 2014. Structural diversity and bioactivities of natural benzophenones. Nat Prod Rep 31: 1158-1174.

Taxonomic sections	Clusia species	% Fruit latex	Colour	Herbarium number
Chlamydoclusia	C. nemorosa G. Mey.	0.87	yellowish green	#95/150
	C. rosea Jacq.	1.14	yellowish green	#95/154
	C. grandiflora Splitg.	0.12	white	#95/153
Criuva	C. criuva Cambess	3.97	yellowish green	#97/247
Criuva	C. parviflora Engl. Nom. Illeg	3.03	yellowish green	#97/7
Phloyanthera	C. hilariana Schltdl.	0.66	white	#97/248
Phloyanthera	C. lanceolata Cambess.	0.56	yellowish green	#96/27
Cordylandra	C. paralicola G. Mariz	1.29	yellowish green	#97/5
	C. weddelliana Planch & Triana	0.46	yellowish green	#2001/57
	C. fluminensis Planch & Triana	1.06	white	#2001/54
	C. panapanari (Aubl.) Choisy	0.67	yellowish green	#95/156
	C. spiritu-sanctensis G.Mariz	0.60	white	#95/185a

			Taxonomic sections
			Cordylandra					Chlamydoclusia			Criuva		Phloianthera
Compounds	^aRI	^bRI	C. paralicola	C. weddelliana	C. fluminensis	C. spiritu-sanctensis	C. panapanari	C. nemorosa	C. rosea	C. grandiflora	C. parviflora	C. criuva	C. lanceolata	C. hilariana
Fatty acid derivatives
2-Methyl butyl acetate	883	881	0.51	-	-	-	-	-	2.42	-	-	5.55	-	-
Undecane	1100	1100	-	-	-	-	-	-	9.70	0.29	-	1.79	-	-
Dodecane	1200	1200	-	-	-	-	-	-	-	-	-	-	-	0.20
Tridecane	1301	1300	-	-	-	0.43	-	-	-	-	-	-	-	0.42
Tetradecane	1400	1400	-	-	7.82	-	-	-	-	-	-	-	-	1.11
Hexadecane	1600	1600	-	-	-	-	-	-	-	-	-	-	-	0.80
Octadecene	1796	1790	-	-	-	-	-	-	-	-	4.41	-	-	-
Hexadecanol	1882	1875	-	-	-	-	3.72	-	10.19	22.72	1.94	-	-	-
Octadecanol	2081	2077	-	-	-	-	-	-	-	-	26.81	-	-	-
Octadecanol acetate	2212	2209	-	-	-	-	-	-	-	-	3.55	-	-	-
Isoprenoids	Subtotal		0.51	-	7.82	0.43	3.72	-	22.31	23.01	36.71	7.34	-	2.53
Isoprenoids
Camphene	951	954	-	-	-	-	-	-	-	-	-	2.93	-	0.30
β-Pinene	981	979	-	-	-	-	-	-	-	-	-	4.08	-	-
α-Terpinene	1015	1017	-	-	-	-	-	-	-	-	-	-	-	0.12
Verbenone	1201	1205	-	-	-	-	-	-	-	31.91	-	-	-	-
cis-Ocimenone	1234	1229	-	-	-	-	-	-	-	8.84	-	-	-	-
trans-Ocimenone	1238	1238	-	-	-	-	-	-	-	1.41	-	-	-	-
δ-Elemene	1340	1338	1.21	-	-	1.35	1.93	-	-	-	-	-	-	-
α-Cubebene	1354	1348	0.54	-	-	-	-	-	-	-	-	-	-	0.54
α-Ylangene	1375	1375	-	-	-	-	-	-	-	-	-	1.45	0.73	-
α-Copaene	1380	1376	1.83	-	8.69	1.41	-	4.32	-	1.30	-	15.58	10.39	1.72
β-Elemene	1394	1390	8.51	1.70	-	2.54	2.28	-	-	-	-	-	-	-
Cyperene	1397	1398	-	-	-	-	-	-	-	-	-	-	3.33	-
α-Gurjunene	1412	1409	-	0.89	-	-	-	-	-	-	-	-	-	-
α-Santalene	1416	1417	-	-	-	-	-	-	4.08	-	-	-	-	-
β-Caryophyllene	1418	1419	2.08	24.05	35.61	0.55	-	21.10	-	2.39	4.12	1.38	36.39	58.11
β-Gurjunene	1435	1433	3.19	7.73	-	-	-	-	-	2.22	-	-	-	-
(E)-α-Bergamontene	1438	1434	-	-	-	36.30	5.52	-	12.67	-	-	4.42	-	-
Aromadendrene	1442	1441	6.25	-	-	-	1.79	-	-	-	-	-	-	-
α-Humulene	1457	1454	-	5.28	2.11	0.98	2.19	-	1.35	0.27	-	-	7.81	18.27
(E)-β-Farnesene	1458	1456	-	-	-	-	-	24.63	-	-	-	-	-	-
Allo-aromadendrene	1460	1460	-	-	-	-	-	-	-	-	11.08	-	-	-
dihydro-Aromadendrane	1463	1462	-	-	-	2.33	-	-	-	-	-	-	-	-
γ-Muurolene	1479	1479	-	-	-	-	13.42	18.71	-	2.53	-	-	3.81	-
ar-Curcumene	1483	1480	-	-	-	-	-	-	5.20	-	-	-	-	-
Germancrene D	1486	1485	44.28	-	8.78	-	10.16	5.50	-	-	12.88	29.03	-	1.85
β-Selinene	1489	1490	10.98	4.44	12.44	-	-	-	3.46	0.97	-	-	1.17	-
Valencene	1492	1496	-	-	-	-	-	-	-	-	-	-	1.26	-
α-Selinene	1494	1498	-	4.35	6.56	-	-	-	-	1.02	-	-	-	-
Bicyclogermancrene	1495	1500	-	-	-	3.14	25.93	-	-	-	-	-	-	-
α-Muurolene	1499	1500	-	-	-	-	-	2.80	-	-	-	5.59	-	2.52
trans-β-Guaiene	1504	1502	-	-	2.18	-	-	-	-	-	-	-	-	-
β-Bisabolene	1506	1505	-	-	-	-	-	-	1.98	-	-	-	-	-
α-Bulnesene	1510	1509	-	25.61	-	-	-	-	-	-	-	-	-	-
γ-Cadinene	1515	1513	-	-	-	5.49	10.84	13.87	-	0.74	3.79	tr	1.40	2.02
δ-Cadinene	1526	1523	12.14	12.34	-	15.30	11.04	-	3.52	0.83	-	5.10		1.69
trans-γ-Bisabolene	1536	1531	-	-	-	23.66	-	-	-	-	-	-	-	-
trans-Cadina-1,4-diene	1537	1534	-	1.53	-	-	-	-	-	0.42	-	-	0.98	-
α-Cadinene	1539	1538	-	-	-	tr	3.64	1.04	-	-	-	9.01	-	0.73
α-Calacorene	1542	1545	-	-	-	-	-	-	8.28	0.30	4.40	-	-	-
(E)-Nerolidol	1567	1563	-	3.41	-	-	-	-	-	-	-	-	-	-
Spathulenol	1573	1578	-	-	6.37	4.81	2.53	4.59	6.72	11.71	-	1.67	-	-
Caryophyllene oxide	1580	1583	-	-	3.45	-	-	-	-	6.86	11.07	-	8.75	9.05
Globulol	1587	1590	-	-	-	-	-	-	-	-	3.96	-	-	-
β-Copaen-4α-ol	1589	1590	-	-	-	-	-	-	-	0.44	-	1.16	-	-
Guaiol	1596	1600	-	-	-	-	-	-	-	-	-	1.13	-	-
Khusimone	1599	1604	-	-	-	-	tr	-	-	-	-	-	-	-
1,10-di-epi-Cubenol	1617	1619	-	-	-	0.55	-	-	-	-	-	-	-	-
10-epi-γ-Eudesmol	1619	1623	-	4.17	5.54	-	-	-	-	-	-	-	-	-
1-epi-Cubenol	1630	1628	-	-	-	-	-	1.32	-	-	-	-	-	-
epi-α-Cadinol	1638	1640	-	-	-	-	-	1.55	0.31	-	-	-	-	-
epi-α-Muurolol	1642	1642	4.16	-	-	-	3.12	-	-	-	3.96	-	-	-
Cubenol	1645	1646	-	-	-	0.78	1.04	-	-	0.21	-	-	-	-
α-Cadinol	1656	1654	-	-	-	-	-	-	-	1.01	-	-	-	-
Khusinol	1677	1680	tr	-	-	-	-	-	-	-	-	-	-	-
14-hydroxi-α-Muurolene	1778	1780	3.17	-	-	-	-	-	-	-	-	-	-	-
Benzenoids	Subtotal		98.34	95.50	91.73	99.19	95.43	99.43	47.57	75.38	55.26	82.53	76.02	96.92
Benzenoids
Benzaldehyde	963	960	-	-	-	-	-	-	-	-	-	3.46	-	-
Acetophenone	1067	1065	0.20	3.83	tr	-	-	0.52	10.49	tr	3.11	2.73	0.58	-
Methyl benzoate	1094	1090	0.33	-	-	-	-	-	-	-	-	-	-	0.46
Ethyl benzoate	1172	1173	-	-	-	-	-	-	-	-	4.53	2.54	-	-
p-Anisaldehyde	1255	1250	0.58	-	0.36	tr	-	-	-	1.21	-	1.11	23.39	-
Others	Subtotal		1.11	3.83	0.36	tr	-	0.52	10.49	1.21	7.64	9.84	23.97	0.46
Others
3-Methylcyclohexanone	951	952	-	-	-	-	-	-	19.56	-	-	-	-	-
	Subtotal		-	-	-	-	-	-	19.56	-	-	-	-	-
	Total		99.96	99.33	99.91	99.62	99.15	99.95	99.93	99.67	99.61	99.71	99.99	99.91

Brasil