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. 2010 Sep 2;15(9):6168–6185. doi: 10.3390/molecules15096168

Comparative Study of the Leaf Volatiles of Arctostaphylos uva-ursi (L.) Spreng. and Vaccinium vitis-idaea L. (Ericaceae)

Niko Radulović 1,*, Polina Blagojević 1, Radosav Palić 1
PMCID: PMC6257750  PMID: 20877214

Abstract

The first GC and GC/MS analyses of the essential oils hydrodistilled from dry leaves of Arctostaphylos uva-ursi and Vaccinium vitis-idaea enabled the identification of 338 components in total (90.4 and 91.7% of the total GC peak areas, respectively). Terpenoids, fatty acids, fatty acid- and carotenoid derived compounds were predominant in the two samples. Both oils were characterized by high relative percentages of α-terpineol and linalool (4.7-17.0%). Compositional data on the volatiles of the presently analyzed and some other Ericaceae taxa (literature data) were mutually compared by means of multivariate statistical analyses (agglomerative hierarchical cluster analysis and principal component analysis). This was done in order to determine, based on the essential oil profiles, possible mutual relationships of the taxa within the family, especially that of species from the genera Arctostaphylos and Vaccinium. Results of the chemical and statistical analyses pointed to a strong relation between the genera Vaccinium and Arctostaphylos.

Keywords: Arctostaphylos uva-ursi (L.) Spreng., Vaccinium vitis-idaea L., essential oil, α-terpineol, linalool, chemometrics

1. Introduction

It has been known for centuries that leaves of Arctostaphylos uva-ursi (L.) Spreng., Ericaceae (Bear's grape, bearberry) possess powerful astringent activity, mainly due to the presence of glycosides such as arbutin [1]. In 1601, Clusius reported its earlier use by Galen (ca. 130–200 C.E.) as a hemostatic. In modern Western medical practice, its use seems to begin with Spanish and Italian physicians (ca. 1730–1740 C.E.) for calculus complaints [2]. For more than 100 years now this plant species has been official in nearly all Pharmacopeias and is widely used for treating bladder and kidney disorders, inflammatory diseases of the urinary tract, urethritis, cystitis, for strengthening and imparting tone to the urinary passages, etc. [1,2]. During collection, bearberry is commonly confused with cowberry (Vaccinium vitis-idaea L.) and box (Buxus sempervirens L.). Poisonous B. sempervirens (similar morphological characteristics, but without the pharmacologically active arbutin) has occasionally been used to adulterate the drug [1,3]. Vaccinium vitis-idaea and other representatives of the genus Vaccinium (Ericaceae), on the other hand, could be regarded as suitable substitutions for A. uva-ursi (comparable content of arbutin and similar pharmacological action of leaves’ infusions) [1]. Some recent studies have shown that biologically active phenologlycosides, simple phenols, flavonoids, tannins, polysaccharides, etc. are also present in V. vitis-idaea and A. uva-ursi [4,5,6,7,8].

It has been previously shown that essential oils may, despite their small yield, contribute to the medicinal properties of the plant [9]. Moreover, volatile metabolites could be potentially used as a tool which could give a quick insight to the presence/absence (i.e. expression) of a certain biosynthetic “apparatus” in some plant taxa, and to some extent, to the (dis)similarity of the compared species on a molecular level [10]. To the best of our knowledge, there are no previous reports on the essential oil profile of A. uva-ursi and there is a limited data concerning the volatiles of V. vitis-idaea and only of the berries [11,12]. Thus, the aim of this work was set to analyze in detail (using GC and GC/MS) and compare the chemical composition of the essential oils hydrodistilled from the dry leaves of A. uva-ursi and V. vitis-idaea, in order to determine if any further phytochemical similarities between the two species exist. Comparison of the compositional data of the oils from a number of Ericaceae taxa (present study and the literature data [13,14,15,16,17,18,19,20,21,22,23]) was achieved using multivariate statistical analyses (MVA: agglomerative hierarchical cluster analysis (AHC) and principal component analysis (PCA)).

2. Results and Discussion

GC and GC/MS analyses of the essential oils extracted from Arctostaphylos uva-ursi and Vaccinium vitis-idaea leaves enabled the identification of 338 different constituents (243 in A. uva-ursi and 187 in V. vitis-idaea, Table 1), representing 90.4 and 91.7% of the total GC peak areas, respectively. The major contributors to the V. vitis-idaea oil were α-terpineol (17.0%), pentacosane (6.4%), (E,E)-α-farnesene (4.9%), linalool (4.7%) and (Z)-hex-3-en-1-ol (4.4%). The same two constituents, α-terpineol (7.8%) and linalool (7.3%), were predominant in the oil of A. uva-ursi, additionally characterized by hexadecanoic acid (4.5%) and (E)-geranyl acetone (4.1%). Another common feature of the analyzed oils was the presence of terpenoids (46.8 and 49.5% in A. uva-ursi and V. vitis-idaea oils, respectively) and fatty acid derived compounds (34.1% - V. vitis-idaea, 10.7% - A. uva-ursi oil) in high relative amounts. Fatty acids and fatty acid esters (F, 11.8%), and carotenoid derived compounds (CD, 14.1%) represented a significant portion of A. uva-ursi oil. The mentioned constituents belonging to F and CD classes were identified in the V. vitis-idaea oil as well, but were present in a considerably smaller relative amount.

Table 1.

Chemical composition of the essential oils extracted from the leaves of Arctostaphylos uva-ursi and Vaccinium vitis-idaea.

RI1 Class Identification2 Compound V. vitis-idaea, % A. uva-ursi, %
725 GL a, b (Z)-3-Penten-1-ol tr
732 GL a, b (E)-3-Penten-2-one tr3 tr
739 MRP a, b, c Pyridine tr
744 GL a, b (E)-2-Pentenal tr tr
762 GL a, b, c 1-Pentanol tr tr
765 GL a, b (Z)-2-Penten-1-ol 0.8 0.2
772 TH a, b 3-Methyl-2-buten-1-ol (syn.4 prenol) 0.1
772 O a, b, c N,N-Dimethyl formamide 0.4
781 TH a, b 3-Methyl-2-butenal (syn. prenal) tr
783 GL a, b, c 2,4-Pentandione (syn. acetyl acetone) tr
801 GL a, b, c Hexanal tr 0.1
824 MRP a, b Methylpyrazine tr
827 O a, b, c Maleic anhydride tr
832 TH a, b, c 2-Methylbutanoic acid tr
828 GL/MRP a, b, c Furfural 0.2 0.8
839 GL a, b, c 4-Hydroxy-4-methyl-2-pentanone tr tr
844 GL a, b (E)-3-Hexen-1-ol tr
854 GL a, b (E)-2-Hexenal tr 0.7
854 GL a, b (E)-2-Hexen-1-ol 1.2
858 GL a, b (Z)-3-Hexen-1-ol 4.4 tr
867 GL a, b, c 1-Hexanol tr tr
863 MRP a, b, c 3-Methylpyridine 0.2
869 MPR a, b α-Angelica lactone tr
892 AE a, b 1-Nonene tr
896 O a, b 2-Methyl-2-cyclopentenone tr
900 TH a, b, c Isopropyl 3-methylbutanoate 0.1
913 GL a, b (E,E)-2,4-Hexadienal tr tr
915 MRP a, b, c 2-Acetylfuran tr 0.2
916 MRP a, b Ethylpyrazine tr
920 MRP a, b 2,3-Dimethylpyrazine tr
935 GL a, b 2-Methylpentanoic acid tr
956 GL a, b (E)-2-Heptenal tr 0.1
959 MRP a, b 3-Ethylpyridine 0.1
959 GL a, b (Z)-3-Hepten-1-ol tr
965 MRP a, b, c Benzaldehyde 0.6 0.2
963 MRP a, b 5-Methyl-2-furancarboxaldehyde tr
967 GL a, b, c 1-Heptanol tr tr
968 MRP a, b 3-Ethenylpyridine 0.4
971 GL a, b, c Hexanoic acid 0.6
973 GL a, b (E)-4-Octen-3-one tr
978 GL a, b 1-Octen-3-ol tr 0.1
978 MRP a, b, c Phenol tr
986 CR a, b 6-Methyl-5-hepten-2-one 0.1
989 O a, b, c Benzonitrile tr
993 GL a, b 2-Pentylfuran tr
995 GL a, b 3-Octanol tr
999 GL a, b (E,Z)-2,4-Heptadienal tr 0.3
1001 MRP a, b 2-Ethyl-6-methylpyrazine tr
1004 MRP a, b 2-Ethyl-5-methylpyrazine tr
1005 MRP a, b Trimethylpyrazine tr
1013 GL a, b (E,E)-2,4-Heptadienal tr 0.7
1019 MRP a, b 5-Ethyl-2-methylpyridine tr
1022 TMM a, b, c Limonene tr
1027 O a, b 2-Ethylhexan-1-ol tr 0.1
1027 TMA a, b, c p-Cymene tr
1031 GL a, b (E)-3-Octen-2-one tr tr
1036 MRP a, b, c Benzyl alcohol 0.7 0.2
1047 MRP a, b, c Phenylacetaldehyde 0.5 1.0
1047 O a, b, c Salicylaldehyde tr
1053 O a, b, c 2-Methylphenol 0.1
1057 A a, b 4-Methyldecane tr
1058 GL a, b (Z)-2-Octenal 0.1
1062 GL a, b, c Pentyl isobutanoate tr
1067 GL a, b (E)-2-Octen-3-ol tr 0.1
1069 GL a, b, c 1-Octanol 0.9 0.7
1071 GL a, b (E,E)-3,5-Octadien-2-one tr
1071 O a, b, c Acetophenone tr
1072 O a, b, c 4-Methylbenzaldehyde tr
1074 O a, b, c 4-Methylphenol tr
1075 TMA a, b, c cis-Linalooloxide (furanoid) 0.5 1.3
1086 O a, b 3-Methylbenzaldehyde tr
1090 TMM a, b α-Cumyl alcohol (syn. 2-phenyl-2-propanol) tr
1092 TMA a, b, c trans-Linalooloxide (furanoid) 0.3 0.9
1093 TMM a, b p-Cymenene tr
1097 GL a, b 1-Nonen-4-ol tr
1098 GL a, b Isobutyl tiglate 0.4
1102 TMA a, b, c Linalool 4.7 7.3
1106 GL a, b, c Nonanal 0.5 tr
1107 TM a, b Hotrienol tr
1107 CR a, b 6-Methyl-3,5-heptadien-2-one 1.8
1111 TMT a, b, c α-Thujone 0.7
1114 O a, b 2,6-Dimethylcyclohexanol tr 0.2
1117 MRP a, b, c 2-Phenyl-1-ethanol 0.6
1120 TMA a, b Myrcenol tr
1121 TMT a, b, c β-Thujone 0.1
1125 TMT a, b Dehydrosabinaketone 0.1
1126 CR a, b, c Isophorone tr
1130 TMP a, b α-Campholenal tr
1140 GL a, b (E)-3-Nonen-2-one tr
1143 O a, b Phenylacetonitrile tr
1145 TMP a, b, c trans-Pinocarveol tr
1145 TMM a, b Lilac aldehyde B tr 0.2
1147 CR a, b 4-Oxoisophorone tr tr
1150 TMB a, b, c Camphor 0.8
1154 TMA a, b Lilac aldehyde A 0.4 tr
1154 GL a, b (E,Z)-2,6-Nonadienal 0.4
1157 TMA a, b Neroloxide tr
1158 TMM a, b, c Menthone 0.2
1161 GL a, b (E)-2-Nonenal tr 0.3
1165 TMA a, b (Z)-β-Ocimenol 0.1
1167 O a, b, c Benzyl acetate tr
1169 TMM a, b, c Menthol 0.3
1169 TMA a, b Lilac aldehyde C tr
1170 F a, b, c Octanoic acid 0.7
1171 TMM a, b α-Phellandren-8-ol tr
1172 TMM a, b p-Mentha-1,5-dien-8-ol tr
1172 TMB a, b, c Borneol 1.4
1173 TMA a, b cis-Linalooloxide (pyranoid) tr
1175 O a, b, c Ethyl benzoate tr
1177 TMM a, b Isomenthol 1.9
1179 TMA a, b trans-Linalool oxide (pyranoid) tr
1181 O a, b 2,4-Dimethylbenzaldehyde tr
1182 TMM a, b Terpinen-4-ol 0.5 1.0
1186 TMP a, b Isoverbanol tr
1188 TMM a, b neo-Isomenthol tr
1189 TMM a, b p-Cymen-8-ol 0.2 0.6
1190 O a, b, c Naphthalene tr
1196 TMM a, b α-Terpineol 17.0 7.8
1200 O a, b, c Methyl salicylate 0.5 0.1
1202 TMP a, b, c Myrtenol 0.1
1203 TMM a, b γ-Terpineol tr
1205 CR a, b Safranal tr 0.2
1207 GL a, b, c Decanal tr 0.1
1213 TMM a, b trans-Piperitol tr
1216 TMP a, b, c Verbenone 0.3
1216 GL a, b (E,E)-2,4-Nonadienal tr tr
1221 TMM a, b 1-p-Menthen-9-al isomer 1 0.4 0.6
1223 TMM a, b, c trans-Carveol tr
1223 TMM a, b 1-p-Menthen-9-al isomer 2 0.5 0.4
1226 CR a, b β-Cyclocitral 0.4 0.2
1231 TMA a, b (Z)-Ocimenone tr
1231 TMA a, b, c Nerol 0.2 0.8
1237 TMM a, b, c Thymol methyl ether
1244 TMM a, b, c Pulegone 0.3
1247 TMM a, b, c Carvacrol methyl ether tr
1249 TMM a, b, c Carvone 0.2
1252 TMM a, b Perilla ketone 0.1
1256 TMA a, b, c Geraniol 1.5 3.0
1259 TMM a, b Piperitone 0.2
1263 GL a, b (E)-2-Decenal 0.5 0.7
1273 TMA a, b, c Geranial 1.3
1275 F a, b, c Nonanoic acid 0.4 0.7
1277 TMM a, b Perilla aldehyde 1.2
1286 GL a, b Vitispirane 0.9
1290 PP a, b, c trans-Anethole 0.6
1290 TMB a, b, c Isobornyl acetate tr
1294 TMM a, b, c Thymol 2.0
1294 AE a, b 1-Tridecene tr
1296 GL a, b (E,Z)-2,4-Decadienal tr tr
1297 TMM a, b, c Menthyl acetate tr
1299 O a, b 2-Methylnaphthalene tr
1300 O a, b, c Indole tr
1300 A a, b, c Tridecane tr
1304 TMM a, b, c Carvacrol 0.9
1304 TMM a, b Perilla alcohol tr
1309 GL a, b Undecanal 0.1
1313 CR a, b Riesling acetal 1.4
1317 O a, b 1-Methylnaphthalene tr
1318 PP a, b 4-Vinylguaiacol tr tr
1319 GL a, b (E,E)-2,4-Decadienal 0.8 1.7
1323 O a, b 2,4,6-Trimethylbenzaldehyde 0.1
1326 GL a, b (Z)-3-Hexenyl tiglate tr
1336 A a, b Branched alkane tr
1341 CR a, b (E,E)-2,5-Epoxy-6,8-megastigmadiene tr
1344 A a, b Branched alkane tr
1353 TMM a, b α-Terpineol acetate 0.7
1359 O a, b 1,1,6-Trimethyl-1,2-dihydronaphthalene 0.2 0.6
1361 PP a, b, c Eugenol 0.7 tr
1363 TMA a, b Hydroxy citronellol(syn. 3,7-dimethyl-1,7-octanediol) tr
1366 GL a, b (E)-2-Undecenal tr 0.2
1367 F a, b γ-Nonalactone tr
1371 CR a, b (E,Z)-4,6,8-Megastigmatriene tr
1370 F a, b, c Decanoic acid tr 0.8
1377 A a, b 3-Methyltridecane tr
1383 CR a, b α-Ionol 0.3
1383 GL a, b (Z)-3-Hexenyl hexanoate 0.8
1384 O a, b, c Biphenyl tr
1388 GL a, b (Z)-3-Hexenyl (Z)-3-hexenoate 0.3
1390 CR a, b (E)-β-Damascenone 0.3
1391 GL a, b (E)-2-Hexenyl caproate tr
1396 AE a, b 1-Dodecene tr
1398 CR a, b (Z)-Jasmone tr
1400 A a, b, c Tetradecane tr tr
1404 CR a, b (2E)-3-(2,6,6-trimethyl-1-cyclohexen-1-yl)-2-propenal tr 0.4
1407 CR a, b Hexahydropseudoionone (syn. tetrahydrogeranyl acetone) tr 0.1
1409 O a, b 2,6-Dimethylnaphthalene tr
1411 AL a, b Dodecanal tr tr
1416 O a, b 1-Ethenylnaphthalene tr
1420 CR a, b (E)-β-Damascone tr
1423 TS a, b β-Cedrene 0.2
1424 O a, b 1,3-Dimethylnaphthalene tr
1427 TSCR a, b, c β-Caryophyllene 2.9 0.9
1433 CR a, b, c (E)-α-Ionone 0.1
1440 TS a, b Calarene (syn. β-Gurjunene) tr
1444 O a, b 2,3-Dimethylnaphthalene tr
1454 O a, b Acenaphthylene tr
1456 CR a, b (E)-Geranyl acetone tr 4.1
1457 A a, b 4-Methylpentadecane tr
1460 TSF a, b (E)-β-Farnesene tr
1462 TSH a, b, c α-Humulene 1.1 1.2
1463 A a, b 2-Methyltetradecane tr tr
1465 F a, b Undecanoic acid 0.2
1476 ALC a, b 1-Dodecanol tr
1483 TSCD a, b γ-Muurolene 0.6
1488 TSGER a, b Germacrene D tr
1492 CR a, b, c (E)-β-Ionone 1.1 1.3
1494 TSED a, b β-Selinene tr
1497 TS a, b α-Zingiberene 0.6
1498 FAD a, b 2-Tridecanone 0.1
1500 TSED a, b δ-Selinene tr
1500 A a, b, c Pentadecane tr tr
1503 TSED a, b α-Selinene 0.8
1503 O a, b Benzyl tiglate tr
1507 TSCD a, b α-Muurolene 0.2
1509 TSAG a, b 4-epi-cis-Dihydroagarofuran tr
1511 TSF a, b (E,E)-α-Farnesene 4.9
1513 AL a, b Tridecanal tr
1513 TS a, b β-Bisabolene 0.3
1514 TSCD a, b γ-Cadinene tr
1521 TSCD a, b δ-Cadinene 0.9
1526 TSED a, b 7-epi-α-Selinene tr
1527 PP a, b, c Myristicin 0.6
1530 TSCD a, b trans-Cadina-1,4-diene tr
1532 O a, b Lilial tr
1535 CR a, b (E,Z)-Pseudoionone 0.3
1538 CR a, b Dihydroactinidiolide 0.1
1542 A a, b Branched alkane tr
1544 TSCD a, b α-Cadinene tr
1550 TSCD a, b α-Calacorene 0.2
1555 TSAG a, b α-Agarofuran 1.8
1561 A a, b 2-Methylpentadecane tr
1565 F a, b, c Dodecanoic acid 0.6 1.8
1571 O a, b 2,3,5-Trimethylnaphthalene 0.2
1571 A a, b 3-Methylpentadecane tr
1576 GL a, b (Z)-3-Hexenyl benzoate tr 0.3
1582 TSF a, b (Z)-Dihydroapofarnesol 0.8
1586 TS a, b, c Spathulenol tr
1587 O a, b 9H-Fluorene 0.6
1589 CR a, b (E,E)-Pseudoionone 0.4
1592 TSCR a, b, c Caryophyllene oxide 0.8
1593 AE a, b 1-Hexadecene tr
1594 O a, b 3,3'-Dimethylbiphenyl tr
1600 A a, b, c Hexadecane 0.7
1601 TS a, b Viridiflorol 0.1
1602 TS a, b 4(14)-Salvialen-1-one tr
1607 TSH a, b Humulene epoxide I 0.1
1611 TS a, b Cedrol 0.2
1614 AL a, b Tetradecanal tr
1615 AL a, b (E)-7-Tetradecenal tr
1619 TSH a, b Humulene epoxide II tr
1629 F a, b, c Isopropyl laurate tr
1629 TSED a, b 10-epi-γ-Eudesmol 3.0
1634 O a, b, c Benzophenone tr
1638 O a, b 4-Methyldibenzofuran tr
1640 TSED a, b γ-Eudesmol tr 0.6
1646 TSCR a, b Caryophylla-3(15),7(14)-dien-6-ol tr
1649 TSCD a, b τ-Cadinol 0.3
1650 TSCD a, b Cubenol tr
1654 TSCD a, b α-Muurolol 0.2
1659 TSED a, b α-Eudesmol tr
1662 TSER a, b Valerianol 1.7
1665 A a, b 2-Methylhexadecane tr
1666 TSCD a, b α-Cadinol 0.2
1667 TSED a, b 7-epi-α-Eudesmol tr
1675 ALC a, b 1-Tetradecanol 0.9
1676 TSF a, b Hexahydrofarnesol 0.1
1683 O a, b Hexyl salicylate tr
1694 AE a, b 1-Heptadecene tr tr
1695 TSCD a, b Amorpha-4,9-dien-2-ol 0.1
1698 TS a, b Acorenone 0.2
1700 A a, b, c Heptadecane 0.3 0.2
1705 TSGER a, b, c Germacrone 1.1
1716 AL a, b Pentadecanal 0.3 0.1
1719 TSF a, b (E,E)-Farnesal tr
1725 O a, b 2,6-Diisopropylnaphthalene 0.2
1727 F a, b, c Methyl tetradecanoate tr
1755 A a, b 5-Methylheptadecane tr
1764 A a, b 2-Methylheptadecane tr
1765 F a, b, c Tetradecanoic acid 1.2
1772 O a, b, c Benzyl benzoate tr 0.2
1784 O a, b, c Phenanthrene 0.1
1794 AE a, b 1-Octadecene tr 0.1
1795 F a, b, c Ethyl tetradecanoate tr
1800 A a, b, c Octadecane 0.1
1818 AL a, b Hexadecanal tr tr
1828 F a, b, c Isopropyl myristate tr 0.1
1839 F a, b 15-Pentadecanolide (syn. exaltolide) tr
1844 TSF a, b (E,E)-2,6-Farnesyl acetate tr
1848 CR a, b Hexahydrofarnesyl acetone 1.7 2.3
1862 F a, b Pentadecanoic acid tr
1876 O a, b, c Benzyl salicylate tr tr
1883 ALC a, b, c 1-Hexadecanol tr
1894 AE a, b 1-Nonadecene tr
1900 A a, b, c Nonadecane tr 0.1
1921 CR a, b (E,E)-5,9-Farnesyl acetone tr 0.7
1928 F a, b, c Methyl hexadecanoate tr tr
1930 O a, b 2-Methylanthracene tr
1941 F a, b (Z)-9-Hexadecenoic acid (syn. palmitoleic acid) 0.2
1950 TD a, b Isophytol tr 0.2
1968 F a, b, c Hexadecanoic acid tr 4.5
1975 TD a, b Sandaracopimara-8(14),15-diene tr
1982 ALC a, b, c 1-Heptadecanol tr
1994 AE a, b 1-Eicosene tr tr
1996 F a, b, c Ethyl hexadecanoate tr 0.2
2000 A a, b, c Eicosane tr 0.1
2003 TD a, b Manoyl oxide 1.4 0.1
2025 TD a, b 13-epi-Manool oxide 2.0
2034 CR a, b (E,E)-Geranyl linalool tr
2070 TD a, b ar-Abietatriene tr
2094 AE a, b 1-Heneicosene tr tr
2100 A a, b, c Heneicosane 0.3 0.1
2116 TD a, b (E)-Phytol tr 3.3
2116 AL a, b Nonadecanal tr
2136 AE a, b, c Linoleic acid 0.3
2138 A a, b Branched alkane tr
2143 F a, b, c Linolenic acid 1.2
2155 F a, b (E,E)-9,12-Octadecadienoic acid (syn. linoleic acid) 0.8
2172 AE a, b 1-Nonadecanol tr
2180 A a, b Branched alkane tr
2194 AE a, b 1-Docosene 0.8 tr
2200 A a, b, c Docosane 0.5 tr
2219 AL a, b Eicosanal tr
2294 AE a, b 1-Tricosene 0.3
2300 A a, b, c Tricosane 2.1 0.2
2395 AE a, b 1-Tetracosene 1.4
2352 F a, b δ-Octadecalactone tr 0.1
2394 AE a, b 1-Tetracosene tr
2400 A a, b, c Tetracosane 1.2 tr
2495 AE a, b 1-Pentacosene tr
2500 A a, b, c Pentacosane 6.4 tr
2596 AE a, b 1-Hexacosene 1.1
2600 A a, b, c Hexacosane 0.6
2700 A a, b, c Heptacosane 2.9
2297 AE a, b 1-Octacosene 1.6
2900 A a, b, c Nonacosane 2.0
2998 AE a, b 1-Triacontene tr
3100 A a, b, c Hentriacontane tr
Total 91.7 90.4
Number of constituents 187 243
Terpenoids (T) 49.5 46.8
Hemiterpenoids (TH) tr 0.2
Monoterpenoids (TM) 27.4 35.6
Oxygenated 27.4 35.6
Hydrocarbons tr tr
Acyclic (TMA) 7.6 14.7
p-Menthane (TMM) 19.8 17.4
Bornane (TMB) 0.0 2.2
Thujane (TMT) 0.0 0.9
Pinane (TMP) tr 0.4
Sesquiterpenoids (TS) 18.7 7.4
Oxygenated 9.2 2.1
Hydrocarbons 9.5 5.3
Farnesane (TSF) 5.7 0.1
Caryophyllane (TSCR) 3.7 0.9
Eudesmane (TSED) 3.0 1.4
Cadinane (TSCD) 0.0 2.7
Germacrane (TSGER) 1.1 tr
Eremophylane (TSER) 1.7 0.0
Salvialane, acorane, bisabolane, aromadendrane, cedrane, gurjunane (TS) 0.6 1.0
Agarofurane (TSAG) 1.8 0.0
Humulane (TSH) 1.1 1.3
Diterpenoids (TD) 3.4 3.6
Phenylpropanoids (PP) 0.7 1.2
Fatty acid derived compounds (FAD) 34.1 10.7
Alkanes (A) 16.3 1.5
Alkenes (AE) 5.2 0.4
Aldehydes (AL) 0.3 0.1
Alcohols (ALC) 0.9 tr
“Green leaf” volatiles (GL) 11.4 8.6
Fatty acids and fatty acid esters (F) 1.7 11.8
Carotenoid derived compounds (CD) 3.2 14.1
Maillard reaction products (MRP) 1.8 2.9
Others 0.7 2.9
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1 Compounds listed in order of elution on HP-5MS column (RI- experimentally determined retention indices on the mentioned column by co-injection of a homologous series of n-alkanes C7-C29); 2 a: constituent identified by mass spectra comparison; b: constituent identified by retention index matching; c: constituent identity confirmed by co-injection of an authentic sample; 3 tr- trace (<0.05%); 4 syn.-synonym.

In respect to the skeleton-types of the identified constituents, the monoterpenoid fractions of both V. vitis-idaea and A. uva-ursi oils could be considered as rather simple. Interestingly, not taking into account some trace constituents, the monoterpenoid fractions of both oils were completely comprised of oxygenated derivatives. In V. vitis-idaea oil only acyclic (7.6%), p-menthane (19.8%) and pinane-type (tr) monoterpenoids were detected. Acyclic (14.7%) and monoterpenoids with a p-menthane (17.4%) skeleton dominated the monoterpenoid fraction of A. uva-ursi oil as well, and only small relative amounts of pinane (0.4%), bornane (2.2%) and thujane-type (0.9%) compounds were detected. α-Terpinyl cation, produced by the biosynthetic cyclization of linalyl diphosphate, the intermediate from which p-menthane type monoterpenoids are derived, is known to be the precursor of other classes of cyclic monoterpenoids including bornanes, pinanes and thujanes [24]. Biosynthesis of linalool is closely related to linalyl diphosphate, and α-terpineol could be considered as a direct biosynthetic product of α-terpinyl cation, formed by quenching the mentioned cation with water [24]. Both linalool and α-terpineol were by far the most abundant compounds in the monoterpenoid fractions of A. uva-ursi and V. vitis-idaea oils. Having the above mentioned in mind, one could speculate that both taxa have a relatively primitive monoterpenoid biosynthetic “apparatus”, capable of producing predominantly metabolites from the “beginning” of the mentioned metabolic pathway. It seems that a similar consideration stands for some other taxa from the genus Vaccinium as well. In different Vaccinium species (V. corrymbosum, V. oxycoccus, V. macrocarpon, V. arctostaphylos) α-terpineol and/or linalool were recognized as major, or one of the major volatile metabolites [14,25,26,27,28,29]. Nevertheless, this should be taken with a grain of salt, since only the volatile metabolites have been investigated. In the studied species monoterpenes could be potentially present as glycosides, and thus non-volatile under hydrodistillation and/or GC conditions. α-Terpineol and some other terpenoid compounds were previously also recognized as V. macrocarpon cuticle wax constituents [30]. According to Croteau et al., the presence of these compounds in the cuticle wax could suggest that these substances might have a certain role in the plants’ defense mechanisms [30].

Although the relative amount of volatile sesquiterpenoids was considerably lower than that of monoterpenoids in both A. uva-ursi and V. vitis-idaea oils, sesquiterpenoid fractions were, concerning skeleton-types of identified constituents, much more heterogenic (Table 1). A number of different skeleton-types of volatile sesquiterpenoids were dominant in the oils of the two taxa: farnesanes (5.7%), caryophyllanes (3.7%) eudesmanes (3.0%) in V. vitis-idaea oil and cadinanes (2.7%), eudesmanes (1.4%) and humulanes (1.3%) in A. uva-ursi oil.

It might be assumed that certain volatiles listed in Table 1, identified in both A. uva-ursi and V. vitis-idaea oils, could be considered artifacts of the isolation procedure, and not direct products of plant metabolism. For example, a number of compounds from the Table 1 are most probably products of Maillard-type reactions including the thermal fragmentation of amino acids and sugars, alone or in conjunction, during hydrodistillation [31]. “Green leaf” volatiles, on the other hand, are most probably produced by enzymatic degradation of unsaturated fatty acids, as in desiccation, i.e. as a stress-induced response of plants, produced during collection and preparation of plant samples [32]. Alongside “green leaf” and other fatty acid derived compounds (FAD), fatty acid and fatty acid esters (F) and carotenoid derived compounds (CD) represented more than one third of both analyzed oils. Volatile profiles of some other representatives of the genus Vaccinium were also dominated by FAD, F and/or CD compounds [13,33,34]. All these species could be considered as essential oil-poor species (oil yield less than 0.1%). All mentioned above seems to further corroborate the hypothesis proposed by us in a previous publication [10]. We have noticed that the correlation between the essential oil yield and composition (classes of compounds) exists [10]. Most frequently, essential oil-rich species (oil yield much higher than 0.1%) produce considerable amount of monoterpenoids or phenylpropanoids, while in the oils of essential oil-poor species, FAD, F and CD compounds are the dominant volatile metabolites [10].

As previously mentioned, there are no reports concerning the volatile metabolites of A. uva-ursi, and there are only two references on V. vitis-idaea volatiles, however different parts of the plant (berries instead of leaves), using a different methodology (minced berries were treated with a pectinolytic enzyme and after that volatiles of the obtained juice and pressed residue were separately studied), have been analyzed [11,12]. Volatile profile of V. vitis-idaea barriers differs significantly from the corresponding profile of the leaves. For example, the most dominant volatile of the pressed residue of minced berries was benzyl alcohol (40.2%), found only as the minor contributor of the leaves’ oil. α-Terpineol and linalool (dominant volatiles of V. vitis-idaea leaves) on the other hand, represented in total only 1.0% of berry extract. This plant organ specification, concerning production/accumulation of volatiles, is not unusual. For example, differences in the chemical composition of Artemisia absinthium root and aerial parts oils pointed out to the possibility that different metabolic pathways could be operational in different organs of the same plant species [35]. Still, some similarities between V. vitis-idaea berry and leaf essential oil profiles could be observed. For instance, fatty acid related compounds, one of the dominant groups of constituents in the leaf oil, represented a significant portion of the berry extract (ca. 20%) [11,12].

Both species analyzed herein belong to the plant family Ericaceae. The latter comprises some 100-125 genera and more than 3,000 species [36] that are, generally speaking, poorly studied in respect to volatile metabolites. Table 2 lists the Ericaceae taxa whose essential oils were previously chemically analyzed using a methodology comparable to that applied in this work [13,14,15,16,17,18,19,20,21,22,23]. Compositional data on the essential oils of the species listed in Table 2 (28 samples in total) were mutually compared by means of multivariate statistical analyses (MVA: AHC and PCA).

Table 2.

List of essential oil samples used in statistical analyses.

Taxon (plant part) Main oil constituent Ref.1 Des.2
Arctostaphylos uva-ursi (L.) Spreng. (leaves) α-Terpineol (7.8%) Present study Obs1
Vaccinium vitis-idaea (leaves) α-Terpineol (17.0%) Present study Obs2
V. arctostaphylos L. (shoots) Hexadecanoic acid (27.0%) [13] Obs3
V. arctostaphylos (aerial parts) α-Terpineol (15.0%) [14] Obs4
Rhododendron mucronatum G. don (flowers) Linolenic acid (39.7%) [15] Obs5
R. simii Planch. (flowers) Linolenic acid (36.4%) [15] Obs6
R. simii (leaves) Phytol3 (15.2%) [15] Obs7
R. naamkwanense Merr. (leaves) 9,12-Octadecatienoic acid (45.3%)4 [15] Obs8
R. anthopogon D. Don (aerial parts) α-Pinene (37.4%) [16] Obs9
R. aureum Georgi. (leaves) Calarene (34.4%) [17] Obs10
R. aureum (leaves) Calarene (66.4%) [17] Obs11
R. aureum (leaves) Calarene (26.2%) [17] Obs12
R. aureum (leaves) Calarene (41.3%) [17] Obs13
R. aureum (leaves) β-Bourbonene (27.4%) [17] Obs14
R. aureum (leaves) Calarene (48.8%) [18] Obs15
R. aureum (leaves) Calarene (36.2%) [18] Obs16
R. aureum (leaves) Calarene (16.2%) [18] Obs17
R. dauricum L. (leaves) trans-Caryophyllene (19.1%) [18] Obs18
R. dauricum (leaves) γ-Cadinene (17.4%) [18] Obs19
R. dauricum (leaves) trans-Caryophyllene (17.0%) [18] Obs20
R. tomentosum (Stokes) H. Harmaja (leaves) (former name Ledum palustre L.) Palustrol (22.8%) [19] Obs21
Ledum palustre L. var. angustum N. Busch Ascaridole (26.8%) [20] Obs22
Erica manipuliflora Salisb. (aerial parts) Heptacosane (19.9%) [21] Obs23
E. manipuliflora (aerial parts) 1-Octen-3-ol (16.2%) [21] Obs24
Gaultheria fragrantissima Wall. (leaves) Methyl salicylate (99.2%) [22] Obs25
G. fragrantissima (steams) Methyl salicylate (99.5%) [22] Obs26
G. fragrantissima (flowering twigs) Methyl salicylate (99.4%) [22] Obs27
Arbutus unedo L. (leaves) (E)-2-Decenal (12.0%) [23] Obs28
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1 Ref.-reference; 2 Des.-designation; 3 Correct isomer not specified in the original reference; 4 Name of component (incomplete and unclear) given as in the original reference.

This was done in order to determine, based on the essential oil profiles, possible mutual alliance of the taxa within the family, especially that of species from the genera Arctostaphylos and Vaccinium. Principal component analysis (PCA) and agglomerative hierarchical clustering (AHC) were both performed using the Excel program plug-in XLSTAT version 2008.6.07. Both methods were applied utilizing the mean values of the relative abundances of the constituents of compared essential oils as variables (only constituents with percentage higher than 1% in at least one sample were taken into account). AHC was determined using Pearson dissimilarity where the aggregation criterion were simple linkage, unweighted pair-group average and complete linkage and Euclidean distance where the aggregation criterion were weighted pair-group average, unweighted pair-group average and Ward’s method. PCA of the Pearson (n) type was performed. Results of the MVA analyses are given in Figure 1 and Figure 2. In the dendrogram of the AHC analysis (Figure 1), four different classes of samples (C1-C4) can be observed. Class C1 (Obs25-Obs27) groups essential oils (almost pure methyl salicylate) obtained from different parts of Gaultheria fragrantissima (wintergreen) [22]. Class C2 consists exclusively of Rhododendron aureum oils (Obs10-Obs17), all characterized with a high level of the sesquiterpene calarene [17,18]. Oils obtained from flowers of R. mucronatum and R. simii (Obs5 and Obs 6; high level of linolenic acid) form a separate class C3 [15]. All other samples [13,14,15,16,17,18,19,20,21,22,23], including those that correspond to A. uva-ursi (Obs1), V. vitis-idaea (Obs2) and V. arctostaphylos (Obs3 and Obs4) are recognized as statistically not different and grouped in C4. It must be stressed that samples Obs1-Obs4 are basically characterized by very low Euclidian distance. In the same time, different species from the genus Rhododendron are separated in statistically different groups (C2, C3 and C4) [15,20]. Results of AHC suggest that taxa from the genera Vaccinium and Arctostaphylos are closely related. This is observable from the PCA biplot as well (Figure 2), where A. uva-ursi (Obs1) and V. arctostaphylos (Obs4) oils are mutually characterized with similar values of F1 and F2 factors. Moreover, samples corresponding to Vaccinium, Arctostaphylos and Arbutus taxa (Obs1, Obs2, Obs4 and Obs28) are, based on PCA results, clearly separated from other considered oils (Figure 2). One could find results of both AHC and PCA a bit surprising, having in mind that classical taxonomy places genera Vaccinium and Arctostaphylos in different subfamilies of Ericaceae (Vaccinoidaea and Arbutoidaea) [37]. Results of molecular studies within the Ericaceae clearly separated taxa belonging to the mentioned genera [37,38]. Nevertheless, mutual alliance of Arbutus and Arctostaphylos (Arbutoidaea; Obs1, Obs22) is recognized by both molecular [37,38] and chemotaxonomical studies (present work).

Figure 1.

Figure 1

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(a) Dendrogram (AHC analysis) representing chemical composition dissimilarity relationships of 28 essential oil samples (observations) obtained by Euclidian distance dissimilarity (dissimilarity within the interval [0, 27000], using aggregation criterion-Ward's method). Four groups of samples (C1-C4) were found. (b) Principal component analysis ordination of 28 oil samples (observations). Axes (F1 and F2 factors-the first and second principal component) refer to the ordination scores obtained from the samples. Axis F1 accounts for ca. 13% and axis F2 accounts for a further 11% of the total variance.

3. Experimental

3.1. Plant material

Leaves of V. vitis-idaea were collected from the slopes of Stara Planina Mountain (near the mountain top Babin Zub), S. Serbia, at the beginning of July, 2007. Voucher specimens were deposited in the Herbarium of the Faculty of Science and Mathematics, University of Niš, under acquisition number 20074. Leaves of A. uva-ursi were obtained from a local pharmacy (in 2006). Botanical identification was performed by N.R.

3.2. Isolation of the essential oils

Air-dried, to constant weight, leaves of A. uva-ursi and V. vitis-idaea (three batches of about 500 g of each sample) was subjected to hydrodistillation with ca. 2 L of distilled water for 2.5 h using the original Clevenger-type apparatus [39]. The semi-solid yellowish essential oils (30 ± 1 mg per batch) of both species were obtained with a yield of 0.06% (w/w, typical value). Due to the small sample size of 30 mg of the isolated essential oils, which were not completely liquid, the volume of the oils was not measured. The obtained oils were separated by extraction with diethyl ether (Merck, Darmstadt Germany) and dried over anhydrous sodium sulfate (Aldrich, St. Louis, MO, USA). The solvent was evaporated under a gentle stream of nitrogen at room temperature, in order to exclude any loss of the essential oil, and immediately analyzed. When the oil yields were determined, after the bulk of ether was removed under a stream of N2, the residue was exposed to vacuum at room temperature for a short period to eliminate the solvent completely. The pure oil was then measured on an analytical balance and multiple gravimetric measurements were taken during 24 h to ensure that all of the solvent had evaporated.

3.3. Gas chromatography and gas chromatography-mass spectrometry

The GC/MS analysis was repeated three times for each sample using a Hewlett-Packard 6890N gas chromatograph. The gas chromatograph was equipped with a fused silica capillary column HP-5MS (5% phenylmethylsiloxane, 30 m × 0.25 mm, film thickness 0.25 μm, Agilent Technologies, Palo Alto, CA, USA) and coupled with a 5975B mass selective detector from the same company. The injector and interface were operated at 250 ºC and 300 ºC, respectively. The oven temperature was raised from 70 ºC to 290 ºC at a heating rate of 5 ºC/min and then isothermally held for 10 min. As a carrier gas helium at 1.0 mL/min was used. The samples, 1 μL of the oil solutions in diethyl ether (1:100), was injected in a pulsed split mode (the flow was 1.5 mL/min for the first 0.5 min and then set to 1.0 mL/ min throughout the remainder of the analysis; split ratio 40:1). mass selective detector was operated at the ionization energy of 70 eV, in the 35–500 amu range with a scanning speed of 0.34 s. GC (FID) analysis was carried out under the same experimental conditions using the same column as described for the GC/MS. The percentage composition was computed from the GC peak areas without the use of correction factors. Qualitative analysis of the essential oil constituents was based on several factors. Firstly, the comparison of the essential oils linear retention indices relative to retention times of C7-C31 n-alkanes on the HP-5MS column [40] with those reported in the literature [41]. Secondly, by comparison of their mass spectra with those of authentic standards, as well as those from Wiley 6, NIST02, MassFinder 2.3. Also, a homemade MS library with the spectra corresponding to pure substances and components of known essential oils was used, and finally, wherever possible, by coinjection with an authentic sample (Table 1). Relative standard deviation (RSD) of repeated measurements (independent sample preparations and GC-MS) was for all substances below 1%. The only exceptions which had higher RSD were minor components such as α-agarofuran, (E)-β-ionone, pulegone, safranal and dodecanoic acid where RSD was 2, 6, 7, 9 and 12%, respectively.

4. Conclusions

Comparison of the compositional data of the essential oils extracted from A. uva-ursi, V. vitis-idaea and 12 other Ericaceae taxa (six different genera; available literature data) pointed out to a high level of similarity of Vaccinium and Arctostaphylos species. Based on the identity and relative abundance of the dominant volatile metabolites produced by the compared Ericaceae taxa, it seems that the level of mutual correspondence between A. uva-ursi and V. vitis-idaea species is more significant than that of any of the two taxa and the rest of the compared species. This is partially due to the fact that α-terpineol and linalool were among the dominant contributors to the volatile profiles of both A. uva-ursi and V. vitis-idaea. Furthermore, the most abundant classes of compounds in both oils were basically the same (monoterpenoids, fatty acid derived compounds and carotenoid derived compounds). All stated above additionally corroborates the same pharmacological applications of two herbs. It must be stressed once again that essential oils may, despite the small yield, contribute to the medicinal properties of the plant [9].

Acknowledgements

The authors are very grateful to the Ministry of Science and Technological Development of Serbia (Project 142054 B), for the financial support of this work.

Footnotes

Sample Availability: Samples of the A. uva-ursi and V. vitis-idaea essential oils are available from the authors.

References and Notes

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