Angelica glauca roots were collected from Himachal Pradesh and Kashmir at various locations during the year 1999-2000.

Terpene hydrocarbons (methyl octene, limonene, beta-phellendrene, beta-pinene), phthalides [(Z)-3-butyli-dene phthalide (Z)- and (E)-ligustilide] and citronellyl acetate showed large quantitative variations of different geographical locations.

In vitro cultivation of Arabidopsis wildtype and mutant plants: Seeds were sterilized according to standard lab routines (EtOH, NaOCl/NaOH) prior to aseptical (in vitro) cultivation in 500 ml screw cap jars on MS medium (4.3 g/l; 50 ml/jar) containing Bacto- and Phytoagar (1:2; 6 g/l) and 30 g/l sucrose. Ten seeds were pipetted into each jar and plants grown for 6 weeks until flowering at a temperature of 20 ℃ under a 16/8 h day/ night regime using fluorescent tubes (Osram Lumilux Plus Eco 36 W). Both Arabidopsis thaliana wildtype plants of ecotype Columbia-0 (Col) and 4 Col-derived T-DNA knock-out mutants (homozygous lines) showing deficiencies in the GLS biosynthesis pathway were used in this study (five parallels for wildtype and mutants): TGG1 (Atg526000; Salk_130469), TGG2 (At5g25980; Salk_038730), Cyp83A1 (At4g13770) and Cyp83B1 (At4g31500; Salk_028573). Greenhouse-cultivation of Arabidopsis ecotypes: The following Arabidopsis ecotypes were used in the study: Columbia (Col), Cape Verde Islands (Cvi), Landsberg erecta (Ler) and Wassilewskija (Ws). Single plants were greenhouse-cultivated on fertilized soil (P-Jord; Emmaljunga Torvmull AB) in plug trays (9 × 6 cells) at a temperature of 20 ℃ (three parallels for each ecotype). Due to the 6-weeks growth period (November/December 2003), the plants were cultivated under a 16/8 h day/night regime using metal halide lamps (Osram HQI-T 400 W) placed 130 cm above the trays. Depending on the ecotypical plant development, whole plants were sampled after 3-4 weeks right before bolting for in vivo studies, while investigations of single plant organs (leaf, stem, inflorescence) were carried out after 5-6 weeks of cultivation.

Metabolites from methionine, leucine and phenylalanine-derived glucosinolates were most abundant (4-methylthiobutyl, 4-methylpentyl, 2-phenylethyl). In addition, 24 monoterpenes, 26 sesquiterpenes and 12 aromatic structures, predominantly observed in inflorescenses, are described. Excluding the vast group of straight chain aliphatic structures, a total of 102 volatile compounds were detected, of which 59 are reported in Arabidopsis thaliana for the first time, thus emphasizing the sensitivity and applicability of solid-phase microextraction for volatile profiling of plant secondary metabolites.

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.

Leaves from mature plants of Artemisia nilagirica var. septentrionalis, before flowering, were collected from different altitudes in Himachal Pradesh such as Shimla (2210 m), Mandi (1044 m) and Manali (2050 m) in June 2005.

The major constituents of the oil show variation with changes in altitude. At lower, middle and higher altitudes, the major constituents of the oil were caryophyllene oxide (28.6%), borneol (35.8%) and camphor (46.9%), respectively. The percentages of alpha-humulene and trans-beta-guaiene also increased, but the percentage of sabinene, trans-sabinene hydrate, 4-terpineol, caryophyllene oxide and humulene epoxide-II decreased with an increase in altitude. The characteristic compounds observed in the plants from lower altitudes were 2-hexene-1-ol, beta-thujone, thujanol, myrtenol and linalyl acetate, while the higher altitude plants were characterized by the presence of alpha-pinene, beta-pinene, limonene, linalool, gamma-gurijunene, germacrene-D and farnesol.

Four kinds of fresh sweet oranges were obtained in the same season, November 2000, in Guangzhou. Citrus sinensis var. Hongjiang (called 'hong jiang chen' in Chinese) and C. sinensis Osbeck var. Anliu (called 'luo gang chen') were obtained at an orchard in Luo gang in Guangzhou (25 km from the center of Guangzhou). Citrus sinensis var. Sihui (called 'sihui ju') was harvested at the Shigou Experimental Farm in Sihui City in Guangdong Province (75 km far away from Guangzhou). Citrus sinensis var. Washington navel (called 'qi chen') which was produced in Jiangxi Province (200 km from Guangzhou; bordering Guangdong Province), was purchased at the wholesale market in Guangzhou. All oranges were kept in a cold room until prepared a few days later.

The peel oil compositions of four kinds of sweet oranges in China, Citrus sinensis Osbeck var. Hongjian, C. sinensis Osbeck var. Anliu, C. sinensis Osbeck var. Sihui and C. sinensis Osbeck var. Washington navel, were investigated by GC and GC/MS. The essential oils were extracted by cold-pressing method. Forty-two to 53 compounds were quantitatively determined for each variety. Their percentages, respectively, were: > 97.3%, > 98.4%, > 97.5% and > 98.0% in hydrocarbons; > 1.5%, > 0.7%, > 0.8% and > 0.9% in total aldehydes; 0.8%, 0.5%, 0.5% and 0.5% in alcohols. Either cis-or trans-limonene oxide was detected in small amounts in each of the four samples, with Hongjiang containing both limonene oxides. delta-3-Carene was commonly quantified at a level of 0.1% in all the samples. The content of aliphatic aldehydes, including octanal, nonanal, decanal and dodecanal, exceeded that of terpene aldehydes, such as neral and geranial in Hongjiang (0.9%) and Washington navel (0.6%), whereas the aliphatic aldehydes in Anliu and Sihui were present to a lesser degree than the terpene aldehydes. Either alpha- or beta-sinensal was detected in trace amounts in each of the four samples. Linalool was the major alcohol in all the samples. Nootkatone was not detected.

PR4 was isolated as an endophyte from the rhizome of Picrorhiza kurroa. Picrorhiza kurroa Royle ex. Benth (Plantaginaceae) is a perennial herb endemic to the north western alpine Himalayas. The endophyte PR4 was grown on PDA and in PDB at 26 ℃ for 15 days with constant shaking at 200 rpm in the latter case.

The two candidate NR-PKSs (PKS_3671 and PKS_4063) show differences in their domain organizations. PKS_3671 possesses two ACP-domains. Apart from that, only PKS_3671 contains a SAT-domain . These domains provide the first building block in the polyketide assembly, which usually is different from the extender unit malonyl-CoA (also known as the 'starter unit effect'). The ACA-synthesis however is believed to involve merely malonyl-CoA molecules. Even though the ACA-producing PKSs MdpG, ACAS, EncA, AptA and ClaG contain SAT-domains, an amino acid sequence alignment of these domains revealed that they all lack the active-site cysteine in the GXCXG motif and therefore most likely have no acyl transferase activity. Instead, all malonate building blocks are assumed to be loaded by the MAT. Under this aspect, the SAT-domain of PKS_3671 (that includes the correct GXCXG motif) likely incorporates a starter unit different from malonyl-CoA indicating that this enzyme is not involved in the biosynthesis of ACA. Therefore, the ACA-synthesizing PKS in C. asteris would rather be PKS_4063 that misses the SAT-domain .In the monodictyphenone and cladofulvin pathways, the cluster-encoded gene products MdpH and ClaH are crucial enzymes pushing the biosynthesis towards emodin. These EthD-domain-containing enzymes are suggested to catalyze the decarboxylation of ACA (3) into atrochrysone (4). Surprisingly, no such EthD-domain is encoded in the whole C. asteris genome. On the other hand, four genes directly attached to the putative ACA-synthase-coding gene pks_4063 show high similarity to genes of non-investigated PKS clusters in other fungi , which indicates an involvement in tailoring reactions of the respective polyketide pathways. According to InterProScan and BLASTp analyses, the genes sky_4060-62 encode a dehydratase and two dehydrogenases potentially catalyzing the multistep conversion of ACA (3) into emodin (1). Gene sky_4059 codes for a monooxygenase that putatively can connect two emodin molecules to the final product skyrin (2) in the style of the monooxygenase ClaM involved in the dimerization of the bisanthraquinone cladofulvin. Thus, the presence of these genes in the gene cluster gives further support to the hypothesis that PKS_4063 is the ACA-synthase in C. asteris. Mutational studies will be done in order to confirm these assumptions after a gene transfer system for this strain has been developed.

PR4 was isolated as an endophyte from the rhizome of Picrorhiza kurroa. Picrorhiza kurroa Royle ex. Benth (Plantaginaceae) is a perennial herb endemic to the north western alpine Himalayas. The endophyte PR4 was grown on PDA and in PDB at 26 ℃ for 15 days with constant shaking at 200 rpm in the latter case.

The two candidate NR-PKSs (PKS_3671 and PKS_4063) show differences in their domain organizations. PKS_3671 possesses two ACP-domains. Apart from that, only PKS_3671 contains a SAT-domain . These domains provide the first building block in the polyketide assembly, which usually is different from the extender unit malonyl-CoA (also known as the 'starter unit effect'). The ACA-synthesis however is believed to involve merely malonyl-CoA molecules. Even though the ACA-producing PKSs MdpG, ACAS, EncA, AptA and ClaG contain SAT-domains, an amino acid sequence alignment of these domains revealed that they all lack the active-site cysteine in the GXCXG motif and therefore most likely have no acyl transferase activity. Instead, all malonate building blocks are assumed to be loaded by the MAT. Under this aspect, the SAT-domain of PKS_3671 (that includes the correct GXCXG motif) likely incorporates a starter unit different from malonyl-CoA indicating that this enzyme is not involved in the biosynthesis of ACA. Therefore, the ACA-synthesizing PKS in C. asteris would rather be PKS_4063 that misses the SAT-domain .In the monodictyphenone and cladofulvin pathways, the cluster-encoded gene products MdpH and ClaH are crucial enzymes pushing the biosynthesis towards emodin. These EthD-domain-containing enzymes are suggested to catalyze the decarboxylation of ACA (3) into atrochrysone (4). Surprisingly, no such EthD-domain is encoded in the whole C. asteris genome. On the other hand, four genes directly attached to the putative ACA-synthase-coding gene pks_4063 show high similarity to genes of non-investigated PKS clusters in other fungi , which indicates an involvement in tailoring reactions of the respective polyketide pathways. According to InterProScan and BLASTp analyses, the genes sky_4060-62 encode a dehydratase and two dehydrogenases potentially catalyzing the multistep conversion of ACA (3) into emodin (1). Gene sky_4059 codes for a monooxygenase that putatively can connect two emodin molecules to the final product skyrin (2) in the style of the monooxygenase ClaM involved in the dimerization of the bisanthraquinone cladofulvin. Thus, the presence of these genes in the gene cluster gives further support to the hypothesis that PKS_4063 is the ACA-synthase in C. asteris. Mutational studies will be done in order to confirm these assumptions after a gene transfer system for this strain has been developed.

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.

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%).

The plant materials were collected for P1: 2900 m, Ait Akak, Oukaimden, Atlas Mts, Morocco, N. Achak, A. Romane and M. Mahroug, 3 trees, ns, 12/12/2003; P2, 2200 m, Plateau of Matat, Atlas Mts, N. Achak, A. Romane and M. Mahroug, 3 trees, ns, 18/03/2003; P3: 2000 m, Foret Islane, Oukaimden, Atlas Mts, N. Achak, A. Romane and M. Mahroug, 3 trees, ns,12/12/2003. A portion of the leaves from each of the three trees (per population) were air dried for 16 days at room temperature (ca. 22 &#8451) to produce the dried leaf samples.

The oil yields from fresh leaves showed on differences among geographical sources. Air dried leaves appeared to yield more oil at the highest elevation (1.03%, Ait Lkak, 2900 m) than lower sites (0.67%, Plateau of Matat, 2200 m; 0.57%, Foret Islane, 2000 m). The essential oils from each geographic site had very similar composition in fresh versus air dried leaves. The essential oils from provenance Ait Lkak and Plateau of Matat were very similar and characterized by a high sabinene content (21.2, 35.9%), in contrast to 10.% sabinene from the provenance Foret Islane. The oil from Foret Islane had a high delta-cadinene content with 12.7%, whereas Aik Akak and Plateau of Matat contained only 0.6 and 0.8%.

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%.

Seeds of P. ruderale were collected from wild plants found on the campus of the Federal University of Vicosa, Minas Gerais state (Brazil), in September 2000. The seeds were cultivated in a greenhouse during the period of February to May 2001; 60 days after sowing, the leaves and flowers were collected at regular intervals of 15 days for the oil isolation.

The oil content found for the leaves of P. ruderale varied during the period of 60 to 120 days, as follows: 13.8 mg/100 g of fresh material after 60 days; 7.5 mg/100 g (75 days); 23.1 mg/100 g (90 days); 10.6 mg/100 g (105 days); 12.5 mg/100 g (120 days). The first floral buds were collected after 105 days of sowing, and its oil content was 45.1 mg/100 g of fresh material. A significant decrease in the production of oil from the buds was observed after 120 days of sowing, when only 23.0 mg oil/100 g of fresh material was obtained. During the period of 90 days to 105 days, a significant decrease in leaf oil content was observed, at the same time the plants were flowering. This data suggests the plants were relocating their resources to produce more oil in the floral buds.

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.

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.

Plant materials were collected from the following localities. A: Antalya: Alanya, Sapadere, Beldibi-Baskoy in July 1991 (ESSE 9562). B: Icel: Anamur, Kas yaylasi in July 1991 (ESSE 9192).

Thirty-nine components were characterized in each oil representing 85-90% of the total components detected with beta-pinene (34-35%) and alpha-pinene (24-25%) as major constituents.

Solanum lycopersicum L. seedlings were grown from commercial seeds (cv. ACE 55 VF). Seeds were surface sterilized by gently shaking them in a 1% NaClO solution for 5 min and rinsed successively 10 times for 5 min in sterile demineralized water. The seeds were pregerminated in seed trays containing autoclaved peat substrate in a climate-controlled chamber (16 h photoperiod at a light intensity of approximately 300 µmol m^-2 s^-1 photosynthetically active radiation, 23-25 ℃ and 60% Relative Humidity). Ninety-five percent of the seeds germinated at 5 seeds/pot, after one week all the seedlings were showing the apical bud and two cotyledons. Seedlings were then selected for uniformity (plant height and number of leaves) from a large population, and were individually transplanted to 1200 ml pots containing autoclaved soil:sand mix (1:2, v/v). Half of the seedlings received the mycorrhizal treatment as described below. Mycorrhizal colonization of germinated tomato seedlings was induced by transplanting the plants into pots containing autoclaved substrate mixed with inoculum. Mycorrhizal plants (AM): plants were inoculated with 20 ml of Endorize IV commercial inoculum containing Glomus mosseae, Glomus intraradices, Glomus sp., infective units not specified (Biorize, Dijon, France) . Plants were supplied weekly with 20 ml/pot of Long Ashton nutrient solution with half of the content of phosphorus .We attempted to obtain mycorrhizal plants (AM) with size and tissue nutrient content similar to those of non-mycorrhizal plants (NAM) by supplementing NAM plants with more phosphate, since AM symbiosis enhances P uptake and this may alter the plant response to drought . Moreover, the use of plants with similar size allows the detection of drought direct effects not mediated by plant size when working with plants in containers, since unequal plant size can be responsible of differences in soil water depletion and plant transpiration, and consequently plants can be exposed to unequal stress. Thus, not mycorrhizal plants were grown on the same autoclaved substrate, without inoculum material, and supplied weekly with 20 ml/pot of full-strength Long Ashton solution containing 41 ppm of P.All of the seedlings were maintained in a climate-controlled chamber (16 h photoperiod at a light intensity of approximately 370 µmol m^-2 s^-1 photosynthetically active radiation, 23-25 ℃ and 60% Relative Humidity). One month after inoculation, plants were transferred to 3 L pots filled with the sterile substrate and kept in the climate chamber described above. Plants were watered with tap water and fertilized as indicated above.To induce an almost natural, reversible drought stress, thus allowing the plant enough time to acclimate, irrigation was stopped 24 h before measurements were taken. These treatments resulted in moderate water stress (lower than -2 MPa). Two stems, each containing 5-6 mature leaves, and one apical stem were selected in each plant for jasmonic acid (JA) treatment. In the JA treatment, the abaxial and adaxial surfaces of six leaves from two different branches were sprayed until runoff with a solution of 0.5 mM of JA (Sigma-Aldrich, St. Louis, MO, USA). The solution was prepared by dissolving JA in acetone and them diluting this mixture with water to 1 mM. Approximately 1.5 ml of JA solution, corresponding to 0.157 mg of JA, were sprayed onto each single leaf. JA-treated leaves were isolated with a protective plastic that prevented the rest of the plant from being treated. The plastic was removed after the spray has dried. Treatments were coordinated so that all plants were tested approximately 14-15 h after JA application to avoid any diurnal effects.Two months after inoculation, gas exchange and VOCs measurements were performed.

Root colonization by AM fungi favoured the leaf production of essential isoprenoids rather than nonessential ones, especially under drought stress conditions or after JA application.

Solanum lycopersicum L. seedlings were grown from commercial seeds (cv. ACE 55 VF). Seeds were surface sterilized by gently shaking them in a 1% NaClO solution for 5 min and rinsed successively 10 times for 5 min in sterile demineralized water. The seeds were pregerminated in seed trays containing autoclaved peat substrate in a climate-controlled chamber (16 h photoperiod at a light intensity of approximately 300 µmol m^-2 s^-1 photosynthetically active radiation, 23-25 ℃ and 60% Relative Humidity). Ninety-five percent of the seeds germinated at 5 seeds/pot, after one week all the seedlings were showing the apical bud and two cotyledons. Seedlings were then selected for uniformity (plant height and number of leaves) from a large population, and were individually transplanted to 1200 ml pots containing autoclaved soil:sand mix (1:2, v/v). Half of the seedlings received the mycorrhizal treatment as described below. Mycorrhizal colonization of germinated tomato seedlings was induced by transplanting the plants into pots containing autoclaved substrate mixed with inoculum. Mycorrhizal plants (AM): plants were inoculated with 20 ml of Endorize IV commercial inoculum containing Glomus mosseae, Glomus intraradices, Glomus sp., infective units not specified (Biorize, Dijon, France) . Plants were supplied weekly with 20 ml/pot of Long Ashton nutrient solution with half of the content of phosphorus .We attempted to obtain mycorrhizal plants (AM) with size and tissue nutrient content similar to those of non-mycorrhizal plants (NAM) by supplementing NAM plants with more phosphate, since AM symbiosis enhances P uptake and this may alter the plant response to drought . Moreover, the use of plants with similar size allows the detection of drought direct effects not mediated by plant size when working with plants in containers, since unequal plant size can be responsible of differences in soil water depletion and plant transpiration, and consequently plants can be exposed to unequal stress. Thus, not mycorrhizal plants were grown on the same autoclaved substrate, without inoculum material, and supplied weekly with 20 ml/pot of full-strength Long Ashton solution containing 41 ppm of P.All of the seedlings were maintained in a climate-controlled chamber (16 h photoperiod at a light intensity of approximately 370 µmol m^-2 s^-1 photosynthetically active radiation, 23-25 ℃ and 60% Relative Humidity). One month after inoculation, plants were transferred to 3 L pots filled with the sterile substrate and kept in the climate chamber described above. Plants were watered with tap water and fertilized as indicated above.To induce an almost natural, reversible drought stress, thus allowing the plant enough time to acclimate, irrigation was stopped 24 h before measurements were taken. These treatments resulted in moderate water stress (lower than -2 MPa). Two stems, each containing 5-6 mature leaves, and one apical stem were selected in each plant for jasmonic acid (JA) treatment. In the JA treatment, the abaxial and adaxial surfaces of six leaves from two different branches were sprayed until runoff with a solution of 0.5 mM of JA (Sigma-Aldrich, St. Louis, MO, USA). The solution was prepared by dissolving JA in acetone and them diluting this mixture with water to 1 mM. Approximately 1.5 ml of JA solution, corresponding to 0.157 mg of JA, were sprayed onto each single leaf. JA-treated leaves were isolated with a protective plastic that prevented the rest of the plant from being treated. The plastic was removed after the spray has dried. Treatments were coordinated so that all plants were tested approximately 14-15 h after JA application to avoid any diurnal effects.Two months after inoculation, gas exchange and VOCs measurements were performed.

Root colonization by AM fungi favoured the leaf production of essential isoprenoids rather than nonessential ones, especially under drought stress conditions or after JA application.

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%).

The aerial parts of T. chamaedrys were collected at the flowering stage in June 2004 near Corti, Corsica, France and near Oristano, Sardinia, Italy

The Corsican and Sardinian oils of T. chamaedrys investigated in this study were qualitatively similar but they differed by the amount of their major components. The major components were beta-caryophyllene (29.0% and 27.4%, respectively) and germacrene D (19.4% and 13.5%, respectively), followed by alpha-humulene (6.8%) and delta-cadinene (5.4%) in the Corsican oil and by caryophyllene oxide (12.3%) and alpha-humulene (6.5%) in the Sardinian oil. These quantitative differences are also noticeable on the amounts of the different class compounds. Especially, the monoterpene hydrocarbons amounted for 10.3% and 4.1% in Sardinian and Corsican oils respectively and the oxygenated sesquiterpenes amounted for 18.9% and only 7.4% in both oils, respectively. Both oils were qualitatively rather similar in comparison with those reported in the literature from various geographic regions. However, among the 87 components identified in this study, 47 minor components (< 0.6%) reported were identified for the first time in T. chamaedrys oil. This study confirms the quantitative variability of the major components according to the plant origin.

The aerial parts of samples from collective populations of T. carnosus were collected during the vegetative phase (February 2000), at the beginning of the flowering phase (May 2000) and during the flowering phase (July 2000) at Quinta do Lago (Algarve). AQLM: collected in May, beginning of flowering phase; AQLJ: collected in July, flowering stage; AQLF: collected in Feb, vegetative stage.

All the oil samples collected in Quinta do Lago (QL) were dominated by borneol (26-31%) and camphene (9-18%), but the third main component varied according to the harvesting period. Bornyl acetate was the third main component (9-13%) in the flower oil and in the aerial parts oils collected in May and July, whereas terpinen-4-ol (8%) was the third main component in oil collected in February from vegetative phase plant material. A fourth main component, alpha-pinene (4-9%), was also present in relative high amounts in the QL oils.

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.