Fresh aerial parts of A. biebersteinii were collected in May and June 2009 at different developmental stages (vegetative, floral budding, flowering and fruit set)from its natural habitat in the Dizin zone, northwest of Tehran, Iran (Latitude: 36° 4′ 52″N, Longitude: 51° 22′ 46″ E, Altitude: 2325-2425 m).

All oil samples from different plant parts and phenological stages were mostly made up of monoterpenoid compounds (88.6 - 99.6%), especially oxygenated ones (52.4 - 82.4%). The oil of the vegetative stage contained high amounts of limonene, 4a-alpha,7-alpha,7a-alpha-nepetalactone, p-cymene and 1,8-cineole. The major constituents in the flower budding stage oil were found to be limonene, 1,8-cineole and 4aalpha-7beta-7aalpha-nepetalactone. In the oil of the fruit set stage, gamma-terpinene, p-cymene and cis-chrysanthenyl acetate were the predominant constituents. On the other hand, the most important compounds from the stem oil were 4a-alpha,7-alpha,7a-alpha-nepetalactone, 1,8-cineole, 4aalpha-7beta-7aalpha-nepetalactone and camphor. 4aalpha-7alpha-7aalpha-nepetalactone, limonene, 1,8-cineole and cis-p-menth-2-en-1-ol were found in high concentration in the oil of leaves, whereas 4aalpha-7alpha-7aalpha-nepetalactone, 4aalpha-7beta-7aalpha-nepetalactone, limonene and p-cymene were present in large amounts in the oil of flowers.

Populations of A. annua cultivar 'Jeevanraksha' and accession Suraksha were grown in the experimental field plot of the Institute at New Delhi. The seeds were sown in January 2004, seedlings transplanted in late February 2004 and aerial parts (flowers, leaves and stems from the upper 0.5 m of crop canopy) sampled in late October 2004.

Ninety-seven compounds comprising 91.3% of the total oil of 'Jeevanraksha' were identified. Forty-three monoterpenes (56.6%), 32 sesquiterpenes (31.1%), and 2 diterpenes (0.2%) comprised bulk of the oil (87.9%). The oil was devoid of artemisia ketone and contained camphor (13.5%), 1,8-cineole (9.4%), trans-sabinol (7.1%), p-mentha-1(7), 5-dien-2-ol (6.3%), myrcene (4.7%), germacrene D (4.4%), (E)-beta-farnesene (3.9%), beta-caryophyllene (3.7%), dihydroartemisinic lactone (3.0%) and p-cymene (2.0%) as the major constituents. Eighty-six compounds representing 93.3% of the composition were identified in the Suraksha oil. This oil contained artemisia ketone (47%), 1,8-cineole (8.4%), camphor (5.9%) and alpha-pinene (5.2%) as the major components.

The aerial parts (~20 cm, 15-100 g) of A. campestris L. from ten different wild populations of Lithuania were gathered at the full flowering stage. Plant material was dried at room temperature (20-25 ℃). Oils (samples 1-10) obtained from Artemisia campestris plants collected at sampling sites (A-I,Y) characterized by locality, city (c.) or district (d.), soil type (Or, ordo; Sn, sand; Sl, sandy loam; Gr, gravel; Lm, loam) and description of natural habitat (Af, abandoned field; Fe, forest edge; Ct, cutting area; Mw, meadow; Rs, roadside; Rv, river valley): A (1) Birstonas c. (Or, Ct); B (2) Palanga c. (Sn, Fe); C (3) Nociunai, Kedainai d. (Or, Mw); D (4) Alytus c. (Sl, Rs); E (5) Moletai c. (Lm, Af); F (6) Kaltanenai, Sencionys d. (Gr, Fe); G (7) Merkine, Alytus d. (Sl, Ct); H (8) Trakai c. (Gr, Af); I (9) Druskininkai c. (Or, Rv); Y (10) Vilnius c. (Gr, Af).

The main chemical profile (ten samples) was characterized by the predominance of germacrene D (9.8-31.2%), while spathulenol, humulene epoxide II and caryophyllene oxide were found as the first major compounds in another three oils. One oil was determined as a mixed chemotype. Some compounds such as gamma-curcumene, alpha-cadinol, (E,E)-alpha-farnesene, beta-ylangene, beta-selinene and humulene epoxide II have been mentioned for the first time among three principal constituents in A. campestris oils. The fifty-six components made up 73.6.1-98.5% of the total content, while the remaining twenty-six volatile compounds were identified in insignificant amounts in the A. campestris essential oils.

Plant material of A. verlotiorum was harvested near Marseille (France) in May (before blooming) and November (full flowering) 2000.

For the oil from the vegetative plants, 50 compounds, representing 99.8% of the oil were characterized. Fifty-nine compounds, representing 99.6% of the oil were identified in the oil from flowering plants. In both cases, the constituents were mainly oxygenated monoterpenes (74% and 88%). The composition of each oil showed only a few differences, as the main components were alpha-thujone (55% and 44%), 1,8-cineole (5% and 15%), beta-caryophyllene (13% and 7%) and beta-thujone (5% and 11%), in the oils of the vegetative plant and flowering plant, respectively. The proportions of the oxygenated compounds seemed to increase during flowering.

Aerial parts of endemic pichana were harvested in December 1996 at different localities of northern Patagonia. Origin: Planicie Banderita, Dept. Confluencia, Province of NeuquCn. Habitat: altitude, 327 m; average temperature in the station, 21.8 ℃; annual precipitation, 125 mm; sandy soils. Aerial parts (5 kg, 2 kg of dried material;humidity, 11%) from four well developed plants at the fullflowering stage (December, 1996). Sample 2 : Origin: RincBn de 10s; Sauces, Dept. of Pehuenclies, Province of Neuqukn. Habitat: altitude, 750 m; average temperature in the station, 20.9 ℃; annual precipitation, 147 mm; sandy and gritty salty soils. Aerial parts (5 kg, 1.85 kg of dried material, humidity, 10%), from two well developed plants at the full flowering stage, and after several days copious rains (December, 1996). Sample 3: Origin: Coronel GBmez, Dept. General Roca, Province of Rio Negro. Habitat: altitude, 242 m; average temperature in the station, 22.5 ℃; annual precipitation, 179 mm; sandy and stony soils. Aerial parts (4.5 kg, 1.3 kg of dried material, humidity, 9%), from 12 young plants at the beginning flowering stage (December, 1996).

Fifty-four components, representing approximately 84.6-97.4% of the oil samples, were identified. The samples consisted mainly of hydrocarbons and oxygenated monoterpenes. The major constituents were limonene (28.7-56.7%), 6R-7R-bisabolone (3.2-9.1%), sabinene (0.1-11.0%) and citronellal (2.4-5.2%). Significant differences among the content of the three samples could be the result of changes in the climatic conditions (sample 2: Rincon de los Sauces, Province of Neuquen, after strong rains) or by translocations in different parts of the plant (sample 3: Coronel Gomez, Province of Rio Negro, more leaves and less stems).

Bocageopsis multiflora leaves were collected in the Adolpho Ducke reserve, Km 26 Manaus - Itacoatiara highway, in the State of Amazonas, Brazil. This species was collected in the rainy (April 2010) and dry seasons (September 2010).

The main constituent of the oil collected in the rainy season was bisabolene (13.2%), while the main constituent in the dry season was spathulenol (16.2%). The highest yield (0.3%) was obtained for the oil collected in the rainy season.

Six samples of Cassinia laevis R. Br. (coughbush, wild rosemary) were gathered from Lowood, 45 km west of Brisbane to Murphy's Creek area 100 km west of Brisbane, Australia from 1994 to 1998. Samples were identified by a LAEV prefix. LAEV 1 and LAEV 4 were collected from the roadside verge of the Gatton-Toowoomba bypass road (Lat. 27° 32′ 21″ S; Long. 152° 14′ 28″ E). LAEV 2 and LAEV 5 were collected from a different location in the same area (Lat. 27° 33′ 08″ S; Long. 152° 15′ 00″ E). LAEV 7 were collected from the Murphy's creek area (Lat. 27° 31′ 05″ S; Long. 152° 04′ 15″ E), growing on the roadside and in an adjacent paddock. Sample LAEV 9, was collected from the roadside area of the Warrego Highway (Lat. 27° 32′ 10″ S; Long. 152° 27′ 12″ E). The collected leaf and flower samples had aromas of trampled grass with a slight hint of curry.

Spathulenol was the major compound in flower oils (8-12%) compared to leaf oils (0.3-4.0%) which had ledol(37.5-53.6%) as the major compound.

Cistus ladanifer was collected from two sites, in July-August 2001, after the flowering season. The major quantity was brought from the wild, where the plant was growing in the mountainous region of the center-interior of the country (site 1). A smaller amount was harvested from a cultivated plant in the north of Portugal (site 2) that was propagated from a wild plant found in the dry plain region in the South of Portugal.

Considering the oil composition of cistus plants from different sites, there were found some differences. The cistus oil of site 2 had a high content on the ocimenone isomers, an absence of trans-pinocarveol and unknown (compound 17) and a higher quantity of less volatile compounds such as sclareol oxide and 15-nor-labdan-8-ol. Cistus oil from site 1 was richer in sesquiterpene alcohols and 2,2,6-trimethylcyclohexanone. The amount of ambrox was the same for both oils. Considering the use of fresh or dry plant, the composition of cistus from site 2 was more affected, decreasing the amount of components of middle to high volatility and increasing the amount of the less volatiles. Drying promoted the doubling of the amount of ocimenone isomers in cistus oil from site 2 and of unknown (compound 21) and sesquiperpene alcohol (compound 29) in cistus from site 1. Again the quantity of ambrox was the same for both oils.

Leaves were collected from in Botucatu/SP, Brazil. 'Point 1' is the Botanical Garden of UNESP classified by semideciduous seasonal forest 1 (SSF 1), 22° 53′ 10.97″ S 48° 29′ 48.92″ W and 888 m a.s.l. The same trees were observed on all points, during the seasons.

Copaiba plants from semideciduous seasonal forests show differences into the phytochemical profile obtained in dry and wet seasons, with presence of monoterpenes alpha-thujene, o-cymene, (Z)-beta-ocimene, (E)-beta-ocimene, gamma-terpinene and terpinolene in point 1 (in the wet season), while Cerrado strictu sensu did not show significant differences in chemical composition of volatile compounds (only alpha-cadinol and seychellene showed significant differences).

The aerial parts of Ducrosia anethifolia (DC.) Boiss. were collected in the wild from Mehdi Abad (Kerman province, in southern Iran) at the flowering stage in June 2006. The material was dried at room temperature.

The 63 components of this interesting plant were identified in the oil of D. anethifolia, representing 94.0% of the oil. alpha-Pinene (11.6%), terpinolene(3.2%) and (z)-beta-ocimene (2.8%) were the main hydrocarbon components present in the oil, while decanal (54.0%), cis-chrysanthenyl acetate(3.2%) and decanoic acid (1.3%) were the major oxygen-containing constituents.

Plant selection and virological tests: Before effecting the collection procedure, heathy and infected plants of E. purpurea grown in the open field at the Herb Garden of Casola Valsenio were selected and labelled by visual inspection of their aerial parts. The infection by CMV was associated with symptoms on both leaves and flowers. The most characteristic symptoms are yellow mosaic, ring and line-patterns on crinkled and deformed leaves that drop prematurely. The flowers, which may be smaller than normal, show color breaking with white or pale stripes on red petals. Shortening of the internodes is also very common, giving the plant a bushy appearance known as stunting. In Italian environmental conditions, these symptoms are best visible in the summer. On the other hand, plants appeared symptom-free were collected as healthy material. Plant collection: About 3-4 Kg fresh aerial part materials (70% stems, 10% leaves and 20% flowers) of healthy E. purpurea plants were collected in June 2000 at almost the end of flowering. An equivalent quantity of CMV-infected plants (evaluated by DAS-ELISA) was also collected; the percentage of leaves in the infected infected was about 6.0% as due to CMV presence that caused the premature leaf drop.

The oil from healthy material was rich in germacrene D (57.8%) and was more abundant. The infected materials afforded a lower oil content and significant quantitative variations in the oil composition. In particular, the observed percentage of germacrene D (52.6%) was reduced as were other sesquiterpene hydrocarbons. These variations, tested to be significant for all the compound-class fractions and individual major components, were ascribed to the cucumber mosaic cucumovirus (CMV) infection, the only fixed-effect variable that might affect the oil composition.

Eucalyptus urophylla and E. grandis were collected in January (summer) and August (winter) 2006 at the mature vegetative state from Goiania city Brazil, and identified by one of the authors (E.P.F.). Leaves from 5-11 randomized individual plants of the same age representing the local population were collected as homogenous samples in each season, dried at room temperature.

The results were submitted to Principal Components and Clusters Analysis which enabled four groups of oils to be distinguished with regard to specimens and harvest seasons: clusters I and II with only E. grandis samples collected in the cold and dry winter and the hot and humid summer, which were characterized by a high percentage of isoleptospermone (9.6% and 13.2%), alpha-pinene (12.2% and 24.7%), p-cymene (20.5% and 14.5%), and alpha-terpineol (14.3% and 4.9%), respectively; clusters III and IV only associated with E. urophylla samples collected in summer and winter with 1,8-cineole (36.6% and 44.7%) and alpha-terpinyl acetate (7.0% and 11.7%) rich oils.

Eucalyptus urophylla and E. grandis were collected in January (summer) and August (winter) 2006 at the mature vegetative state from Goiania city Brazil, and identified by one of the authors (E.P.F.). Leaves from 5-11 randomized individual plants of the same age representing the local population were collected as homogenous samples in each season, dried at room temperature.

The results were submitted to Principal Components and Clusters Analysis which enabled four groups of oils to be distinguished with regard to specimens and harvest seasons: clusters I and II with only E. grandis samples collected in the cold and dry winter and the hot and humid summer, which were characterized by a high percentage of isoleptospermone (9.6% and 13.2%), alpha-pinene (12.2% and 24.7%), p-cymene (20.5% and 14.5%), and alpha-terpineol (14.3% and 4.9%), respectively; clusters III and IV only associated with E. urophylla samples collected in summer and winter with 1,8-cineole (36.6% and 44.7%) and alpha-terpinyl acetate (7.0% and 11.7%) rich oils.

Plant material was collected at vegetative stage (stems and leaves,September 2005) and at flowering stage (leaves and flowers,December 2004), inCuritiba,Parana state, Brazil.

Thirty-four components were identified, representing more than 80% of total oil. The major components were beta-caryophyllene (flowers-12.8%), caryophyllene oxide (stems-17.2%), globulol (stems-16.5%; leaves-22.5% at vegetative stage and 18.9% at flowering stage), 1-epi-cubenol (stems-10.9%), epi-alpha-muurolol (stems-16.8%) and alpha-cadinol (stems-12.1%; flowers-10.1%).

Fresh F.angulata were leaves gathered and air dried in May, 2004 and the seeds collected in October, 2004 from both habitats (Shahoo and Nevakoh Mountains), Kermanshah Province western Iran.

The oil yield from seed was 5-fold that from leaves (3.2%/100g compared to 0.63%/100g). Cis-ocimene was the major constituent of the seed oil from both regions (64.8% and 76.11%) and a prominent constituent (>20% of the total oil) of the leaf oils of both habitats. alpha-Pinene was the next main component (7-27%) of all 4 oils. Seed oils, with one major component (cis-ocimene), differed from the leaf oils, which were composed mostly of 3 components (alpha-pinene, cis-ocimene, & germacrene D). Distinctions between the oils of the two habitats were less marked than the leaf-oil/seed-oil differences; the cis-ocimene content was higher and alpha-pinene was less in both seedand leaf-oils of the Shahoo habitats than the Nevakoh ecotype; trans-verbenol was absent from the Shahoo leaves, but reached a content of 5.8% in Nevahoh leaf-oil. Further distinctions were found in the content/presence/absence of 20-30 minor components of the oils.

Aerial parts of H. altaicus Willd. (Novopokr.) plants were randomly collected from the wild at four different altitudes, as described below, during the 1999-2001 vegetation periods. All the collections of the plant samples were carried out during massive bud formation and the beginning of flowering. Sample # 1 (3.4 kg) was collected on July 14, 1999 from LAT: 53° 05′ LON: 85° 00′, 330 m, Altai Region, Troiszkii Raion, around the village of Taldinka, 4-5 km below the Bolshoi Rechke, facing southwestern Sopki, Tipchakovo-Heteropalusovo-Pavilnaya steppe. Sample # 2 (10.5 kg) was collected on July 28, 1999 from LAT: 51°, LON: 86° 40′, 600 m, Altai Republic, Ongudaiskii Raion, at the right side of the delta of Lake Ursup, surrounding Stepushka village, along the roadside. Sample # 3 (8.5 kg) was collected on July 30, 2000 from LAT: 51° 39′ LON:79° 59′, 120 m of Altaiskii Krai, Litovskii Raion, 2 km southwest of the Ustianka village, along the roadside. Sample # 4 (6.5 kg) was collected on August 2, 2001 at LAT 50° 11′ LON 87° 53′, 1550 m of Altai Republic, Kosh-Agachiskii Raion, 24 km away from Kurai village, towards North-Tchuiskoe mountain chain following the right side of lake Tete where there is a mixture of heavy weeds.

The oil obtained from 330 m had alpha-pinene (18.6%), myrcene (18.6%), beta-phellandrene (17.2%), (E)-beta-ocimene (12.9%) and germacrene D (11.9%), while samples from 600 m consisted of myrcene (26.4%), alpha-pinene (23.2%), beta-phellandrene (18.0%), (E)-beta-ocimene (9.9%), germacrene D (4.3%) and sabinene (4.2%). The oil from 120 m had -pinene (22.0%), beta-phellandrene (21.6%), myrcene (19.5%), trans-beta-ocimene (11.3%), germacrene D (7.2%) and limonene (4.5%) as major components. At 1550 m the major components were germacrene D (22.0%), myrcene (18.0%), beta-phellandrene (14.0%), alpha-pinene (11.3%) and (E)-beta-ocimene (9.2%).

It was collected in Lujan, Ayacucho Department, San Luis, Argentina, in the vegetative flowering stage (February 1997) and at flowering-fructification (April 1996).

Flowering and flowering-fructification, did not differ in regard to the composition of analyzed sesquiterpenes but showed variation in the relative concentration of one of its constituents. Twenty-four compounds were identified, which represented 93-5% of the oil in the flowering stage and 92.5% of it in the flowering-fructification one. The oil was found to contain beta-caryophyllene (14.3-12.0%), germacrene D (14.7-15.3%), curzerene (11.5-12.7%) and bicyclogermacrene (12.1-14.2%) as major compounds.

H. pectinutu is an odoriferous plant and occurs as a natural weed on the Fiji Islands and in West Africa as a winter hardy bush. In India, it grows as an erect perrennial shrub in Assam, Bengal and Madras regions. Tlie leaves are ovate and the leaf margins range from crenate to serrate. The flowers are pale purple to yellow in cymose clusters, arranged unilaterally. The nutlets are small, oblong and black.

The major compounds present in the Indian oil were sabinene (27.8%), beta-pinene (6.7%), limonene (4.03%), alpha-terpinolene (6.0%), caryopliyllcne (17.2%), alpha-bergamotene (4.1%) and a C20H32-diterpene (5.8%). Other major hydrocarbons present were gamma-terpinene (1.4%), alpha-humulene (1.1%), beta-selinene (1.0%) and gamma-elemene (2.7%). The oil is rather poor in oxygenated terpenoids, the only major oxygen compounds detected were terpinen-4-ol(3.1%), spathulenol(1.1%), an unidentified sesquiterpene alcohol (1.4%) and trans-alpha-bergamotot (2.5%). The total oxygenated compounds constituted about 11% of the oil.

Samples of M. ericifolia leaves were obtained from 19 locations as follows: DL3104- 3110, Coopernook, New South Wales (NSW), 31° 49′ 31″ S, 152° 36′ 48″ E (Site No. 1); DL3114-3120, Hawks Nest, NSW, 32° 40′ 09″ S, 152° 10′ 12″ E (Site No. 2); DL3240-3244, Hexham, NSW, 32° 48′ 50″ S, 151° 42′ E (Site No. 3); DL3245-3249, The Entrance, NSW, 32° 22′ 24″ S, 151° 28′ 19″ E (Site No. 4); DL3397-3401, Tuggerah Lake, NSW, 33° 21′ S, 151° 27′ E (Site No. 5); DL3250-3254, Georges River, NSW, 33° 58′ 42″ S, 151° 00′ 14″ E (Site No. 6); DL3255-3259, Berry, NSW, 34° 46′ 37″ S, 150° 45′ 27″ E (Site No. 7); DL3260-3264, Lake Durras, NSW, 35° 36′ 00″ S, 150° 16′ 17″ E (Site No. 8); DL3265- 3269, Wallaga Lake, NSW, 36° 23′ 43″ S, 150° 03′ 04″ E (Site No. 9); DL3270-3274, Wallagoot, NSW, 36° 44′ 50″ S, 149° 55′ 46″ E (Site No. 10); DL3275-3279, Genoa, Victoria (Vic), 37° 25′ 56″ S, 149° 38′ 41″ E (Site No. 11); BVG3024- 3028, West of Lakes Entrance, Vic, 37° 48′ S, 148° 03′E (Site No. 12); BVG3014-3018, West of Lang Lang, Vic, 38° 13′ S, 145° 30′ 13″ E (Site No. 13); BVG3019-3023, East of Welshpool, Vic, 38° 38′ 28″ S, 146° 30′53″ E (Site No. 14); ACC1019/1-2, 5-7, Nelson on the Glenelg River, Vic, 38° 03′ S, 141° 00′ E (Site No. 15); KJ1-5, Airport Flinders Island, Tasmania (Tas), 40° 05′ S, 148° 00′ E (Site No. 16); KJ6-10, Lackrana Road Flinders Island, Tas, 40° 18′ S, 148° 06′ E (Site No. 17); ACR1848/1-3, Woolnorth Point, Tas, 40° 38′ 30″ S, 144° 43′ 30″ E (Site No. 18); JB4509, Robins Island Track, Tas, 40° 45′ S, 144°53′E (Site No. 19). The majority of samples were collected during June to December 1999 with the exceptions being sites 5, 15 and 18, which were collected during July to October 2000. Leaf material totaling about 100 g of fresh leaves and twigs was obtained mainly from five widely spaced individual trees per location.

Oil composition varied quantitatively throughout the species range rather than qualitatively in an apparent association with latitude of occurrence. Linalool and linalool oxide were abundant in the oils from the north of the species range in New South Wales with a gradual southerly decline in these compounds to central Victoria with concomitant increase in the proportions of 1,8-cineole, alpha-terpineol and limonene. The most southerly populations sampled in southern Victoria and Tasmania gave oils containing relatively high proportions of 1,8-cineole (mean 34.5%) and low proportions of linalool (3%). Four populations from the Central Coast of NSW (Coopernook, Hawks Nest, The Entrance and Tuggerah Lake) provided the greatest opportunity of identifying seed trees that combine the attributes required for plantation development. The tree that had the best combination of oil traits (DL 3116 from Hawks Nest) had an oil yield of 4.5%, a linalool content of 60% and a 1,8-cineole content of 16%.

One hundred grams of mature leaves were collected from 2 to 10 widely spaced trees per site and sent to Sydney for analysis as soon as possible after collection. Samples usually arrived in the laboratory within 48 h of collection. The majority of the sampling was done between December 1998 and October 1999. Seasonal trends in oil yields and composition are confounded in the data on geographic variation, but these were considered minor in the context of this study.

Chemotype 1 is comprised of E-nerolidol (74-95%) and linalool (14-30%) and is found from Sydney, north along the east coast of Australia to Selection Flat, New South Wales, with an isolated occurrence near Maryborough, Queensland. Two divisions occur in this chemotype which are based on the presence or absence of significant proportions of linalool (14-40%). Chemotype 2 contains 1,8-cineole (10-75%), viridiflorol (13-66%), alpha-terpineol (0.5-14%) and beta-caryophyllene (0.5-28%) in varying proportions and order of dominance in the oils. It is found throughout the distribution of the species, from Sydney to Papua New Guinea and New Caledonia. Within chemotype 2 there appears to be a continuous spread of oil composition without formation of any further discrete divisions as in chemotype 1. Analyses have shown that M. quinquenervia trees that occur at latitudes south of 25d S have high oil yields (1-3% w/w%, fresh leaves) and comprise chemotypes 1 and 2. North of 25d S, however, chemotype 1 does not occur and oil yields amongst the Australian populations are uniformly low (0.1-0.2%).

Plants were collected in the Inner plain, the Sharon plain and the kava valley.

The major constituent of all three oils was found to be 1,8-cineole (26.4-34.5%) followed by menthone (10.0-16.7%), pulegone (7.0-7.5%), and isomenthone (4.7-7.8%). Despite some differences in the component proportions, the plants of all three populations clearly belong to the same chemotype.

Dry leaves of Menlba piperita L. 'Kliment-63' and 'Zefir' of 1997 crop were used.

The oil yield from 'Zefir' was 0.97% and that from 'Kliment-63' was 0.54%. The oil from 'Zefir' was found to be rich in menthol (46.2-50.2%) and menthyl acetate (16.8-22.5%). In the oil from 'Kliment-63,' the content of these components was lower, while the menthone content was higher (20.0-23.1%).

Plant material: Leaves of M. spicata plants were collected from a wild population of Mt. Pangeon (alt. 600 m, 40° 55′ N/ 24° 12′ E). Collections were conducted every month during the growing period (April to October).

The oil content ranged from 0.1-1.8%, with the maximum values in late summer/early autumn. The essential oil obtained from the leaves was characterized by a very high content in linalool, i.e. 85.0-93.9% of the total oil (highest percentage in mid-autumn). Other oil constituents occurring in much lower amounts were germacrene D (up to 4.2%), beta-caryophyllene (up to 2.6%) and 1,8-cineole (up to 2.1%).

The aerial parts of M. biflora collected during November 1993 and June 1994 were used for the investigation.

The major constituents of the oil were neral (25.3-32.2%) and geranial (26.7-41.3%). The oil produced in the winter was found to contain higher amounts of oxygenated monoterpenes than the oil produced in the summer.

Myrtle (M. communis var. italica) aerial parts were collected monthly during 2006-2007 from Jbal Stara of Haouaria region in North Tunisia, belonging to a subhumid bioclimate.

In conclusion, high fluctuations were observed in the oil yields and composition of different parts of Myrtus communis var. italica during all the collecting periods. They could be explained by genetic and environmental factors. Moreover, significant differences were revealed in the main oil compounds. alpha-Pinene percentages showed the most remarkable changes among the different part oils. So, leaf oils contained more alpha-pinene than those of the fruits and stems during the myrtle vegetative cycle.

Biological material for these investigations comes from two distant collection sites: Suva planina (mountain in the east of Serbia) and Durmitor (mountain in Montenegro). All specimens (aerial parts of the plants) were collected in 1994 in the blooming stage and/or in the pre-blooming stage.

The results obtained show that though the yields of oils were barely influenced by plant growth stage, they varied appreciably according to the origin of the plant material: pre-blooming, Suva Planina (Serbia): 0.67%; blooming, Suva Planina (Serbia): 0.70%; blooming, Durmitor (Montenegro): 0.40%. Thirty-six components were identified. 1,8-Cineole was always predominant (60%); its concentration was lower (40%) just before blooming. Also present were germacrene D (2-15%), beta-caryophyllene (4-7%), alpha-terpineol (5-7%) and caryophyllene oxides (2-6%). In general, the chemical composition of N. nuda depended more strongly on growth stage than habitat. The only exception was caryophyllene oxide which was three times more abundant in the oil from Montenegro than in that from Serbia.

Seeds of Ocimum basilicum cv. keskenylevelu provided from Hungary, were used in this study. Potted seedlings of Ocimum basilicum were subjected to study the effect of different irrigation rigimes on the essential oil content and composition at experimental farm of college of agriculture, Tarbiat Modarres, University, located in Tehran. (1215 m above sea level, latitude 35° 43′ north, altitude 51° 8′ east). The seeds were sown in spring of 2001 in pots. The irrigation regimes to induce of water stress were: 100%, 85%, 70% and 55% of field capacity. This percentage of field capacity kept constant in the soil by daily weighting of pots. The soil was sandy-loam with 22.6% of field capacity. The harvest of whole plants was performed at the beginning of the flowering stage.

The essential oil content of herb increased from 1.12 to 1.26% as plant water deficit increased (till 70% of field capacity). The number of component of the oil of Ocimum basilicum increased as water stress increase. Amount of the main constituents of the oil such as linalool, methyl chavicol, 1,8-cineole and trans alpha-bergamotene significantly affected by water stress.

MATERIAL AND METHODS: The study was separated in two experiments performed in our research station Campus Rural of The Federal University of Sergipe (UFS), Sao Cristovao city, Sergipe State, from December 03, 2002 to April 28, 2003. First harvesting: The first harvesting (Experiment 1) was performed 40 days after seedlings transplantation during full bloom on 03/06/2003. Harvesting was performed cutting plants at 20 cm height from the soil. The collected material consisted on separating leaves and inflorescences from the stalk. In the first experiment only used leaves in the analysis. Randomized block design in a 3x4 factorial scheme with three replications was used. Each plot was composed of five plants. Treatments were: three harvesting periods (8:00; 12:00, and 16:00 h) combined with three drying temperatures (40, 50, and 60 ℃) and fresh leaves. Second harvesting: To perform the second harvesting (Experiment 2) we collected the regrowth of plants used in Experiment 1. Plants were harvested fifty three days after the first harvesting (on 04/28/2003) at 8:00 h using the same procedures as the first one; however both leaves and infl orescences were used in the analysis. Randomized block design with three replications was used. Treatments were drying periods of 0, 1, 2, 3, 4, 5, 6, 7, 9, 11, 13, and 16 days for leaves and infl orescences in ovens with air renewal and circulation (Marconi model MA-037/5) at 40 ℃.

Harvesting performed at 8:00 h and 12:00 h provided higher essential oil yield. After five days drying, the concentration of linalool raised from 45.18% to 86.80%. O. basilicum should be harvested during morning and the biomass dried at 40 ℃ for five days to obtain linalool rich essential oil.

The study was conducted in North-Central Anatolia under semi arid conditions. Seeds of 18 basil landraces (O. basilicum L.) were collected from local farms and home gardens in Turkey. To examine essential oil composition of the basil landraces without environmental influences, the plants were grown under identical (same environmental and soil conditions) conditions. Seeds were sown on a medium (1:1:1 washed sand, horse manure and field soil) in greenhouse conditions on March 25, 2003. Seedlings were grown until the 3-5 leaf stage. The seedlings were transplanted into pilots in the Gaziosmanpasxa University Experimental Research Station on May 15, 2003. The plants were harvested at the full blooming stage and dried at 35 ℃ for essential oil isolation.

Variation of essential oils in the landraces was subjected to cluster analysis, and seven different chemotypes were identified. They were (1) linalool, (2) methyl cinnamate, (3) methyl cinnamate/linalool, (4) methyl eugenol, (5) citral, (6) methyl chavicol (estragol), and (7) methyl chavicol/citral. Methyl chavicol with high citral contents (methyl chavicol/citral) can be considered as a 'new chemotype' in the Turkish basils.

Plant material and horticultural practice: The experiments were conducted at the Universidade Federal de Lavras between November 2005 and January 2006. Seeds of O. selloi were sown in commercial substrate [Plantmax (Eucatex, Sao Paulo, SP, Brazil)] contained in 72-cell plastic trays and maintained in the greenhouse under intermittent nebulization for 60 days. Seedlings were transplanted to 10 L pots containing a substrate consisting of soil, matured cattle manure and sand (5:3:2), and cultivated under three different light regimes, namely, full sunlight, and sunlight with blue or red shading. Each treatment was repeated seven times and two plants were employed per repetition.

The compositions of the oils varied according to the quality of light. Although the qualitative profiles of the oils of plants grown under full sunlight or red shading were similar, that obtained from plants grown under blue shading presented a larger number of constituents. The highest level of methyl chavicol (93.2%), the major component of the oil, was observed in plants grown under full sunlight.

Experimental: Two hundred grams of healthy mature intact leaves were harvested from each of the taxa growing on their own rootstocks at the UC South Coast Research and Extension Center. flocc = P. americana var. floccosa from Mexico D-7; stey = P. americana var. steyermarkii from Mexico El Salvador 3-22-16; nubi = P. americana var. nubigena from Guatemala 45-C-1; mex = P. americena var. drymfolia from Tasco, Mexico; guat = P. americana var. guatemalensis cult. Nimlioh from Florida; bwl = P. ameticana var. americana cult. Trapp from Florida.

Analysis of oils showed the presence of over 90 components, of which 76 were identified. P. schiedeana oil was found to contain alpha-pinene (23.7%), beta-pinene (23.2%) and beta-caryophyllene as major components. The major constituents of P. americana var. floccosa and P. americana var. steyermarkii were alpha-pinene (10.9%, 7.6%), beta-pinene (20.6%, 10.4%), alpha-terpineol (9.6%, 7.9%), beta-caryophyllene (12.6%, 8.4%), viridiflorene (0.1%, 10.3%) and globulol (0.1%, 9.2%), respectively. The oils of P. americana var. nubigena and P. americana var. drymifolia contained alpha-terpineol (18.4%, 393%) and methylchavicol (12.4%, 40.2%), as major components, respectively. P. americana var. guatemalensis was found to be rich in beta-caryophyllene (38.3%), while the oils of P. americana var. americana and P. primatogena contained alpha-pinene (27.5%) and beta-pinene (40.9%), and alpha-pinene (24.6%), beta-caryophyllene (20.7%) and germacene D (10.1%).

Five different populations of P. spicatus were collected in different geographical regions of the northeast of Brazil. Populations I: (Locality: Morro do Chapeu,Bahia, harvesting: 02.19.94); Populations II: (Locality: Maranguape,Ceara, harvesting: 06.01.97); Populations III: (Locality: Jacobina,Bahia, harvesting: 02.19.94); Populations IV: (Locality: Cocalzinho,Ceara, harvesting: 02.22.94); Populations V: (Locality: Sitio dos Moreiras,Pernambuco, harvesting: 02.22.94)

The aliphatic ketones 2-undecanone, 2-tridecanone and 2-pentadecanone were present in samples of all populations. 2-Tridecanone (1.7-84.7 %) was detected in 30 out of 34 samples analyzed. It was the main component in all samples of root barks, except one where 2-pentadecanone (24.7%) was the major component. 2-Undecanone, beta-eudesmol and sabinene were the major components of leaf oils.

Two samples were collected in Sao Goncalo do Abaete, one in July 2000 and the other in November 2005, in periods of post-anthesis and preanthesis, respectively.

Thirty compounds were detected in the samples collected in Sao Goncalo do Abaete. Among the identified compounds, 53.8% are sesquiterpenes and 42.3% are monoterpenes. The majority components in the two samples were neral and geranial. The sample in anthesis presented a lower percentage of neral (21.4%) and geranial (36.5%) than the sample in pre-anthesis, whose percentages of neral and geranial were 33.6% and 47.2%, respectively.

Plant materials were collected from Chalous Road (north of Tehran province) both at the flowering stage in June and the seed stage in September 2003. The fresh plants were dried at room temperature. Dried stems/leaves (S/L) (collected during flowering stage), seeds (S) were hydrodistilled for 3 h in a Clevenger-type apparatus to produce the oils.

The major constituent in the stem/leaf oil was trans-alpha-bergamotene (77.1%), whereas the major constituent of the seed oil was pregeijerene (87.0%). Nonadecane (8.6%) were the other major constituents in the stem/leaf.

The branches of pine were collected in July, 1996 in 15 different locations in Lithuania in the following regions: Western part (Silute, Jurbarkas, Kursiu Nerija), Eastern part (Salcininkai, Zarasai, Moletai), Southern part (Varena, Trakai, Radviliskis) and central part (Ukmerge, Jonava, Kaisiadorys). The branches in each location were collected from the trees in approximately 1 km radius.

More than 70 constituents were identified (64 positively and 10 tentatively) in the oils. alpha-Pinene (18.5-33.0%) and delta-3-carene (9.1-24.6%) were dominating constituents with the only one exception when the germacrene-4-ol content in one of the samples was 13.2%. The important bornyl acetate content varied from 0.5% to 3.0%. The main sesquiterpenes were beta-caryophyllene, germacrene D, bicyclogermacrene, delta-cadinene, gamma-cadinene, germacrene D-4-ol, cubenol (2.0-5.1%) and alpha-cadinol (1.9-7.7%).

S. aucheri var. aucheri was collected in Karaman: Ermenek to Mutt Road on July 19,1995; Salvia aucheri var. canescens was collected in Karaman: Ermenek, Tekecati Valley on July 19,1995.

Eighty components were characterized in the Salvia aucheri var. aucheri oil, with camphor (21.1%), 1, 8-cineole (20.3%), borneol (7.8%), spathulenol (6.3%) and camphene (5.3%) as major constituents. 1, 8-Cineole (25.2%), camphor (17.9%), borneol (10.6%), alpha-pinene (5.4%) and camphene (5.3%) were identified as major constituents among the 88 components characterized in the oil of Salvia aucheri var. canescens.

Aerial parts of both varieties(Salvia euphratica Montbret et Aucher ex Benth. var. euphratica and Salvia euphratica Montbret et Aucher ex Benth. var. leiocalycina) were collected in Malatya, Turkey in June 1999.

Ninety-five compounds in var. euphratica and 94 compounds in var. leiocalycina were characterized representing 93% and 95% of the total components detected, respectively, with 1,8-cineole (13.8% and 15.2%) and myrtenyl acetate (15.9% and 13.9%) as main constituents.

Aerial parts were collected in Van and Erzurum in eastern Turkey. A) Van: Van to Ercis road 35th km on June 8, 2001 at an altitude of 1850 m. B) Erzurum: Campus area of Ataturk University on July 30, 2001 at an altitude of 1850 m.

Dried aerial parts of S. limbata collected from two localities in Turkey. Oils yielded similar compositions: 70-80% of the oil consisted of monoterpenes and 15-20% of sesquiterpenes. The Erzurum sample contained 3.7% of a diterpene identifi ed as 8,13-epoxy-15,16-dinor-labd-12-ene. Alpha-Pinene or 1,8-cineolerich Salvia oils are used as herbal tea in Turkey.

200 g of fresh flowering spikes were collected randomly at full bloom stage (browning of lower floret stage) from the 2006-2007 crops of clary sage cultivar CIM-Chandni cultivated at CIMAP Lucknow and resource center Purara, Uttarakhand. The oil of Kashmir origin was collected from the Chemistry division of IIIM Jammu.

Linalool (23.6%), alpha-terpineol (3.8%), linalyl acetate (51.2%), beta-caryophyllene (3.2%), germacrene D (1.3%) and sclareol (1.3%) were recorded in the oil S. sclarea cultivated in Lucknow UP while the Kashmir oil sample possessed the highest percentage of linalyl acetate (60.8%) and lowest linalool (14.5%) along with alpha-terpineol (1.8%), geranyl acetate (2.2%), beta-caryophyllene (1.9%), germacrene D (2.6%) and sclareol (1.3%) as the other minor constituents. In contrast, the oil of S. sclarea from Purara in Uttarakhand showed highest percentage of linalool (29.8%), alpha-terpineol (5.3%) and sclareol (2.3%) and the lowest linalyl acetate (45.7%) among all the three samples.

Satureja cuneifolia Ten. growing wild in Middle Anatolian provinces of Turkey were collected at various growth stages: a =from Konya, collected in June, before flowering; b = from Konya, collected in July, from flowering plants; c =from Konya, collected in August, full-bloom plants.

In the oils of S. cuneifolia, 38 compounds were identified, with thymol (43.6-65.5%), carvacrol (4.7-31.2%), gamma-terpinene (trace-13.7%) and p-cymene (trace-11.5%) being dominant.

The plant material was collected from different regions of Turkey. B = Canakkale: Gokceada, Ulukaya hill, August 1995; C = Canakkale: Gokceada, Doruktepe hill, August 1995; D = Canakkale: Gokceada, Kekliktepe hill, August 1995.

Carvacrol (52-56%) was found as the major component of these oils.

Fresh plant materials were obtained in 2004 and 2005. S. thymbra 1(vegetative stage: just before flowering, date: June 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 2(vegetative stage: full flowering, date: July 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 3(vegetative stage: after flowering, date: Aug 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 4(vegetative stage: fruiting, date: Sept 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 5(vegetative stage: fruiting, date: Nov 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 6(vegetative stage: fruiting, date: Feb 7, 2005, location: Mt. Immitos, altitude(m): 350); S. thymbra 7(vegetative stage: before flowering, date: May 7, 2005, location: Mt. Immitos, altitude(m): 350); S. parnassica 8(vegetative stage: before flowering, date: June 16, 2004, location: Mt. Parnon, altitude(m): 1800); S. parnassica 9(vegetative stage: just before flowering, date: July 16, 2004, location: Mt. Parnon, altitude(m): 1800); S. parnassica 10(vegetative stage: full flowering, date: Aug 16, 2004, location: Mt. Parnon, altitude(m): 1800); S. parnassica 11(vegetative stage: after flowering, date: Sept 16, 2004, location: Mt. Parnon, altitude(m): 1800).

It is evident that the phytochemical content of the essential oils for both Satureja species varied greatly, depending on the period examined, and showed large prevalence of phenolic content. It must also be pointed out that regardless of the vegetative stage of the plant collected, the sum of the two isomeric phenol monoterpenes (carvacrol and thymol) and their biosynthetic monoterpene precursors p-cymene and gamma-terpinene represented always the bulk of each essential oil (~76%). More specificallysfor both species-during their premature vegetative stage, gamma-terpinene constitutes the major component of their essential oils. The approach of the flowering period results in the simultaneous gradual diminishment of monoterpene precursors and the prevalence of their phenolic metabolites. Thus, essential oils obtained from plants collected during the 'just before their flowering' stage contain thymol as their major component, which constitutes 27.88 and 38.51% of the total oil content for S. thymbra and S. parnassica, respectively. On the other hand, during their full flowering period carvacrol prevails as the major component, accounting for 39.10% for S. thymbra and for 34.61% for S. parnassica. The end of the flowering stage delineates a sharp decrease of carvacrol levels and the predominance of thymol as the major component of the essential oils. A few months later, as the premature vegetative stage approached, the level of gamma-terpinene was restored. The content of p-cymenesthe other major monoterpene precursor-fluctuated seasonally in a manner similar to that shown by gamma-terpinene. Other monoterpene hydrocarbons such as myrcene and alpha-terpinene were also detected in smaller quantities, whereas various monoterpene alcohols such as linalool, borneol, and terpin-4-ol were found mainly in the oils obtained after the flowering stage. Finally, it is notable that the oils obtained during the just before the full flowering period contain beta-caryophyllene as one of their major components.

Fresh plant materials were obtained in 2004 and 2005. S. thymbra 1(vegetative stage: just before flowering, date: June 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 2(vegetative stage: full flowering, date: July 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 3(vegetative stage: after flowering, date: Aug 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 4(vegetative stage: fruiting, date: Sept 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 5(vegetative stage: fruiting, date: Nov 7, 2004, location: Mt. Immitos, altitude(m): 350); S. thymbra 6(vegetative stage: fruiting, date: Feb 7, 2005, location: Mt. Immitos, altitude(m): 350); S. thymbra 7(vegetative stage: before flowering, date: May 7, 2005, location: Mt. Immitos, altitude(m): 350); S. parnassica 8(vegetative stage: before flowering, date: June 16, 2004, location: Mt. Parnon, altitude(m): 1800); S. parnassica 9(vegetative stage: just before flowering, date: July 16, 2004, location: Mt. Parnon, altitude(m): 1800); S. parnassica 10(vegetative stage: full flowering, date: Aug 16, 2004, location: Mt. Parnon, altitude(m): 1800); S. parnassica 11(vegetative stage: after flowering, date: Sept 16, 2004, location: Mt. Parnon, altitude(m): 1800).

It is evident that the phytochemical content of the essential oils for both Satureja species varied greatly, depending on the period examined, and showed large prevalence of phenolic content. It must also be pointed out that regardless of the vegetative stage of the plant collected, the sum of the two isomeric phenol monoterpenes (carvacrol and thymol) and their biosynthetic monoterpene precursors p-cymene and gamma-terpinene represented always the bulk of each essential oil (~76%). More specificallysfor both species-during their premature vegetative stage, gamma-terpinene constitutes the major component of their essential oils. The approach of the flowering period results in the simultaneous gradual diminishment of monoterpene precursors and the prevalence of their phenolic metabolites. Thus, essential oils obtained from plants collected during the 'just before their flowering' stage contain thymol as their major component, which constitutes 27.88 and 38.51% of the total oil content for S. thymbra and S. parnassica, respectively. On the other hand, during their full flowering period carvacrol prevails as the major component, accounting for 39.10% for S. thymbra and for 34.61% for S. parnassica. The end of the flowering stage delineates a sharp decrease of carvacrol levels and the predominance of thymol as the major component of the essential oils. A few months later, as the premature vegetative stage approached, the level of gamma-terpinene was restored. The content of p-cymenesthe other major monoterpene precursor-fluctuated seasonally in a manner similar to that shown by gamma-terpinene. Other monoterpene hydrocarbons such as myrcene and alpha-terpinene were also detected in smaller quantities, whereas various monoterpene alcohols such as linalool, borneol, and terpin-4-ol were found mainly in the oils obtained after the flowering stage. Finally, it is notable that the oils obtained during the just before the full flowering period contain beta-caryophyllene as one of their major components.

The aerial parts (~35 cm) of each taxa growing wild in eight localities of Almeria province were collected in May 1996. All samples were collected at full flowering. Sideritis pusilla (Lange) Pau ssp. pusilla var. typica, Population/location (UTM): Los Matarines (30SWF7992); Sideritis pusilla ssp. pusilla var. carthaginensis Font Quer, Population/location (UTM): Rambla del Hacho (30SWF7178); Sideritis pusilla ssp. pusilla var. granatensis (Pau) Font Quer, Population/location (UTM): Gafarillos (30SWG8702); Sideritis pusilla ssp. almeriensis (Pau) Malagarriga var. typica, Population/location (UTM): Sierra de Gador, Cerro de los Lobos (30SWF3575); Sideritis pusilla ssp. almeriensis var. littoralis Font Quer, Population/location (UTM): Los Morales (30SWF6775); Sideritis pusilla ssp. almeriensis var. salina Font Quer, Population/location (UTM): Los Pedregales (30SWG7835); Sideritis pusilla ssp. flavovirens (Rouy) Malagarriga, Population/location (UTM): Velez Rubio, Cerro del Huezno (30SWG8965); Sideritis pusilla ssp. osteoxylla (Pau) Pallares, Population/location (UTM): Cabo de Gata, Cerro de S. Miguel (30SWF7165)

Monoterpene hydrocarbons, alcohols, sesquiterpenes and diterpenes were the main constituents in all samples. Among these, alpha-pinene (7.1-25.4%), sabinene (5.9-20.4%), fenchone (0.9-19.3%), limonene (1.2-7.4%) and 1,8-cineole (1.8-15.6%) were the major compounds. The results confirm that there are differences between varieties and subspecies, while cluster analysis revealed that the oil composition potentially has chemotaxonomical significance for this taxon.

Fresh aerial parts of the S. trilobata were collected from CSIR-Central Institute of Medicinal and Aromatic Plants, Research Centre Pantnagar (Uttarakhand) in summer (vegetative stage), rainy (vegetative stage), autumn (flowering stage) and winter (flowering stage) seasons. The experimental site is located between coordinates 29.02° N, 79.31° E and an altitude of 243 m in foothills of northern India.

Volatile oil yield varied from 0.18 to 0.25% in different seasons, with the maximum in winter season. Altogether, 43 constituents, representing 96.1-97.3% of the total oil composition were identified. Major constituents of the oils were alpha-pinene (78.6-83.3%), alpha-phellandrene (1.3-4.1%), sabinene (1.4-1.9%), limonene (1.2-1.9%), beta-pinene (1.0-1.6%), camphene (0.7-2.0%), 10-nor-calamenen-10-one (<0.05-1.5%), germacrene D (0.1-1.4%) and gamma-amorphene (<0.05-1.3%). The comparative results showed no big differences in the oil composition of this plant due to season of collection.

Plant material and isolation procedure: Aerial parts of the plant were collected from two regions, from Kazeroon in southern Iran and Shahr-e-kord in western Iran at the time of flowering in June 2002.

The main components of the oil of S. pilifera collected from Kazeroon, in southern Iran, were spathulenol (15.8%), cis-chrysanthenol (15.3%), beta-caryophyllene (8.4%) and cis-chrysanthenyl acetate (6.9%), while for the plant collected from Shahr-e-kord, in western Iran, they were cis-chrysanthenyl acetate (21.8%), linalool (18.9%), terpinen-4-ol (11.9%) and cis-chrysanthenol (9.2%).

Talauma ovata was collected from October 2003 to February 2005. Leaves and trunk bark from the same set of plants were collected in the four seasons: spring (October 15th, 2003), autumn (April 10th, 2004), winter (July 17th, 2004) and summer (February 15th, 2005). In addition, trunk bark was also collected on January 22nd, 2004 (summer). The plant material was harvested from wild-growing population in Santos Dumont City, Minas Gerais State, Brazil, (21° 28′ 03″ S, 43° 39′ 26″ W), at 1000 m of altitude.

In each season the composition of trunk bark oils was similar to leaf oils, with mainly quantitative differences. However considerable seasonal variation was observed. Significant levels of monoterpenes were found only in autumn. The content of oxygenated sesquiterpenes was highest in samples of spring (October) and decreased in summer (January and February), reaching the lowest level in autumn (April) and increasing again in winter (July). In trunk bark oils the main constituents were: spathulenol, alpha-eudesmol, linalool, trans-beta-guaiene and caryophyllene oxide. The major component in all samples of trunk bark was spathulenol. Its level was highest in October (46.8%), decreased in January (33.3%), remained stable in April and July (18.0%) and increased again in February of next year (27.7%). Levels of alpha-eudesmol were high in spring (13.0%) and autumn (11.5%). Linalool peaked only in April, while trans-beta-guaiane peaked in July (11.1%). Caryophyllene oxide ranged between 10.7-2.0%. The level was highest in January, decreased regularly until July and increased slightly again in October. In leaf oils the main components were: spathulenol, germacrene B, germacrene D, caryophyllene oxide and viridiflorol. Spathulenol was the major component in sample of spring (34.4%), but decreased gradually until winter, when reached the lowest level (9.4%). Caryophyllene oxide showed a similar pattern, varying from 14.1% (spring) to 2.4% (winter). An inverse effect was observed for viridiflorol, which increased from 0.1% in October to 13.7% in July. Important levels of alpha-eudesmol were observed in October (12.3%) and February (9.5%). The percentage of germacrene D was highest in summer, while germacrene B showed high amounts in autumn and winter. The seasonal changes in oil composition of T. ovata can be associated with cycle of life of plant (flowering, fruiting and vegetative stages) and climatic parameters such as intense raining in the spring and summer.

Plant materials were collected during the flowering period in July 2002 from the Dumluca Mountain in the vicinity of Divrigi village of Sivas city at 1900 m altitude and Saksagan Gorge in Saimbeyli village of Adana city at 1900 m altitude.

The flower, stem and root oils of T. cadmeum ssp. orientale collected from the Adana location were characterized with alpha-thujone (25%, 5.2%), cis-linalool oxide (6.8%, 12.8%), trans-chrysanthenyl acetate (5.8%, 8.5%) for flower and stem oils, and beta-eudesmol (10.3%, 6.2%, 13.8%); in addition, stem oil contained 1,8-cineole (6.6%) and root oil contained hexadecanoic acid (6.0%), spathulenol (5.8%) and beta-muurolol (5.3%). The flower and stem oils of T. cadmeum ssp. orientale collected from the Sivas location were characterized with camphor (25.9%, 14.8%), borneol (15.4%, 25.8%) and alpha-thujone (7.8%, 5.5%); in addition, stem oil contained 1,8-cineole (7.4%) and root oil contained nonacosane (16.2%), spathulenol (6.8%) and hexadecanoic acid (5.8%).

Wild growing Tanacetum dolichophyllum samples were collected during the period of full flowering, between September-October 2009 from high alpine meadows of Western Himalaya (Uttarakhand, India): Sample I (Dayara, altitude 3200 m) and Sample II (Tungnath, altitude 3800 m).

Plant collected from Dayara meadow (Sample I) afforded cis-lanceol (11.8%), beta-pinene (10.7%), (E)- beta-farnesene (7.4%), alpha-bisabolol (7.2%), beta-eudesmol (5.2%) and terpinen-4-ol (5.1%) as the major constituents, whereas in the sample collected from Tungnath (Sample II) beta-eudesmol (31.4%), alpha-bisabolol (10.7%) were the most abundant components followed by neryl acetate (5.8%) and (E)-beta-farnesene (5.7%). The composition was dominated by sesquiterpene hydrocarbons and oxygen containing sesquiterpenes (49.2-71.1%). The oils are clearly different from those of all other previously reported T. dolichophyllum oils.

Aerial parts of T. larvatum were collected in July and August during a five-year period, starting in 2001, in Montenegro on several locations: Planinica (Sample a), Visitor (Sample b) and Sinjajevina (Sample c).

Sixty-four components were identified, representing 83.1%, 96.6% and 89.4% of the total oils content in the Planinica [Sample a], Visitor [Sample b] and Sinjajevina [Sample c], respectively. The major constituent in Samples a and b , was oxygenated monoterpene, trans-sabinyl acetate (38.1% and 55.8% respectively). Monoterpene hydrocarbons, beta-pinene (13.5%) and santolinatriene (30.6%), were found to be the dominant components in Sample c. The toxic trans-sabinyl acetate was present only in traces in this sample. trans-Chrysanthenyl acetate, as one of major components in feverfew essential oil, has not been previously identified in the investigated essential oils.

Aerial parts of T. larvatum were collected in July 2002, during the period of full flowering from two locations in Montenegro: Mt. Komovi (Sample I) and Mt. Prokletije (Sample II), altitude ca. 1900 m.

About 40 compounds were identified, representing ~89% and 96% of the total oil content in the Samples I and II, respectively. trans-Sabinyl acetate was found to be the dominant component (51.2% and 69.7%). Among the rest of compounds beta-pinene (7.7% and 4.3%) and camphor (6.3% and 4.3%) were the most abundant in both samples.

Herbal parts were collected from A = Eskisehir: Suluagac village in Turkey, altitude 1100 m, in July 1990 and B = Corum: Osmancik, Berk village in Turkey, altitude 580-600 m, on 22 June 1993.

One chemotype (Suluagac village, Eskisehir, Turkey) contained carvacrol (21.59%), p-cymene (17.80%) and thymol (14.10%); and the other chemotype (Berk village, Corum, Turkey) contained alpha-terpinyl acetate (23.80%), borneol (12.85%), linalool (13.67%) and thymol (11.31%) as major constituents.

Plant materials were collected from the following localities in north western Turkey. A = Trabzon: Caykara, Soganli dag on July 28, 1994; B = Bayburt: Caykara, Mohakambo yaylasi on July 25, 1994; C = Trabzon: Koprubasi, Vizara yaylasi on July 20, 1994.

One hundred and four compounds were identified representing 97.5-99.5% of the total components detected in thymol/carvacrol (50.14/10.67%), thymol/linalool (23.14/20.24%) and linalool/alpha-terpinyl acetate/geraniol (21.55/16.70/11.17%) rich oils.

Aerial parts of the plant were collected from four localities: A = Kirklareli: Karadere in May 1991; B = Kirklareli: Karahamza Village in May 1990; C = Kirklareli: Evciler Village on 13 June 1993; D = Kirklareli: Korukoy on 25 May 1994

The four oils obtained from plants collected in different localities of the same region gave quite different compositions as follows: A: thymol (10.5%), 1,8-cineole (9.96%), p-cymene (9.48%), carvacrol (5.28%); B: beta-caryophyllene (29.50%), carvacrol(20.59%); C: thymol (34.7%), beta-caryophyllene (12.74%), carvacrol (5.24%); D: beta-caryophyllene (56.48%), germacrene D (11.12%), carvacrol (4.85%). Since the identities of the plant materials were checked repeatedly, any misidentification is ruled out. Except for A and C, all the other materials showed beta-caryophyllene as the major constituent. Carvacrol (20.59%) was present in good amount in the oil of B. In A, however, high percentages of 1,8-cineole (10%) and p-cymene (9.5%) were significant. This oil contained only a trace amount of beta-caryophyllene. Four isomeric caryophyllene alcohols were detected in the oil B. The results clearly indicate that the oil of T. striatus var. interruptus has no consistency and we can safely suggest that there are at least three chemotypes, namely thymol/1,8-cineole/p-cymene-type; thymol/beta-caryophyllene-type; and beta-caryophyllene-type, of this species.