S. baicalensis Georgi plants were grown under greenhouse conditions for 1 month and then transferred to the experimental farm of Chungnam National University (Daejeon, Korea). After flowering, the plants were dissected into the roots, stems, leaves, and flowers. All samples were immediately frozen in liquid nitrogen and then stored at 80 °C and/or freeze-dried for RNA isolation and HPLC analysis.

The samples were ground in a mortar with liquid nitrogen and total RNA was extracted from frozen powder using a Plant Total RNA Mini Kit (Geneaid, Taiwan) according to the manufacturer’s instructions. Gel electrophoresis and spectrophotometer were performed to test the quality and concentration of total extracted RNA, respectively. For first-strand cDNA synthesis, 1 µg of high-quality total RNA was used for reverse transcription using the ReverTra Ace-R kit (Toyobo, Japan). A 20-fold dilution of the 20 µL resulting cDNA was used as template qRT- PCR.

In another study (unpublished data), we obtained 39,581 different genes from S. baicalensis using next generation DNA sequencing platforms (Roche/454 GS_FLX+ and Illumina/Solexa HiSeq2000). A partial-length cDNA encoding PSY and full-length cDNAs encoding PDS, ZDS, CHXB, and ZEP were indentified from this database. These proteins were then analyzed for homologies with known sequences and designed as SbPSY, SbPDS, SbZDS, SbCHXB, and SbZEP (GenBank accession numbers: KC417312, KC417313, KC417314, KC417315, and KC417316, respectively).

The deduced amino acid sequences of carotenoid biosynthetic genes from S. baicalensis were analyzed for homology using the BLAST program at the NCBI GenBank database (http://www.ncbi.nlm.nih.gov/ BLAST). Sequence alignments were carried out using BioEdit Sequence Alignment Editor, version 5.0.9 (Department of Microbiology, North Carolina State University, Raleigh, NC, USA). The predicted molecular mass of protein was calculated by online website (http://www.sciencegateway.org/ tools/proteinmw.htm).

QRT-PCR primers amplified five target carotenoid biosynthetic genes and Actin housekeeping gene (HQ847728) of S. baicalensis were designed using the Primer3 website (http://frodo.wi.mit.edu/primer3/) (Table 1(Tab. 1)) and then tested for the specificity by PCR. For quantification of standard, the PCR products amplified from cDNA were purified, and the concentration of the products was measured to calculate the number of cDNA copies. The expression of five carotenoid biosynthetic genes was calculated by the method of relative quantification to Actin as the reference. Real-time PCR reactions were carried out in a 20-µl reaction mix containing 5 µl of template cDNA, 10 µl of 2× SYBR Green Realtime PCR Master Mix (Toyobo, Japan), 0.5 µl of each primer (10 µM), and DEPC water. Thermal cycling conditions were as follows: 95 °C for 5 min; 40 cycles of 95 °C for 15 s, 56 °C for 15 s, 72 °C for 20 s. PCR products were analyzed using Bio-Rad CFX Manager 2.0 software. Three replications for each sample were used for real-time analysis.

Extraction and measurement of carotenoids by high-performance liquid chromatography (HPLC) were performed as described by our group (Kim et al., 2012[16]). Briefly, carotenoids were released from the S. baicalensis samples (0.02 g) by adding 3 mL of ethanol containing 0.1 % ascorbic acid (w/v), vortex mixing for 20 s and placing in a water bath at 85 °C for 5 min. The carotenoid extract was saponified with potassium hydroxide (120 µL, 80 % w/v) at the 85 °C water bath for 10 min. After saponification, samples were placed immediately on ice, and cold deionised water (1.5 mL) was added. ß-Apo-8'-carotenal (0.2 mL, 25 g/mL) was added as an internal standard. Carotenoids were extracted twice with hexane (1.5 mL) by centrifugation at 1,200 × g to separate the layers. Aliquots of the extracts were dried under a stream of nitrogen and re-dissolved in 50:50 (v/v) dichloromethane/methanol before analysis by HPLC. The carotenoids were separated on a C30 YMC column (250 × 4.6 mm, 3 µm; Waters Corporation, Milford, MA, USA) by Agilent 1100 HPLC (Massy, France) equipped with a photodiode array (PDA) detector. Chromatograms were generated at 450 nm. Solvent A consisted of methanol/water (92:8 v/v) with 10 mM ammonium acetate. Solvent B consisted of 100 % methyl tert-butyl ether. Gradient elution was performed at 1 mL/min under the following conditions: 0 min, 90 % A/10 % B; 20 min, 83 % A/17 % B; 29 min, 75 % A/25 % B; 35 min, 30 % A/70 % B; 40 min, 30 % A/70 % B; 42 min, 25 % A/75 % B; 45 min, 90 % A/10 % B; and 55 min, 90 % A/10 % B. Carotenoid standards were purchased from CaroteNature (Lupsingen, Switzerland). For quantification purpose, calibration curves were drawn by plotting at four different concentrations of carotenoid standards according to the peak area ratios with ß-apo-8'-carotenal.

SbPSY was composed of 585 bp encoding a partial open reading frame (ORF) of 195 amino acids. A BLAST search at the amino acid level showed that SbPSY exhibited high homology to other PSYs (Figure 2(Fig. 2)). Specifically, SbPSY shared 86 % identity and 95 % similarity with Nicotiana tabacum PSY, 86 % identity and 93 % similarity with Coffea canephora PSY, 86 % identity and 93 % similarity with Solanum lycopersicum PSY, and 83 % identity and 93 % similarity with Populus trichocarpa PSY. The trans-isoprenyl diphosphate synthase, for the head-to-head condensation reaction (trans-IPPS-HH) domain and aspartate-rich region (DXXXD, where X encodes any amino acid) conserved in other PSY genes were found in SbPSY (Ohnuma et al., 1996[22]; Rasid et al., 2008[24]).

SbPDS was 2348 bp long and had an ORF of 1710, encoding a protein of 569 amino acids with a predicted molecular mass of 63.38 kDa (Figure 3(Fig. 3)). SbPDS was 85 %, 84 %, 83 %, and 83 % identical to PDS from Diospyros kaki, Vitis vinifera, N. benthamiana, and Prunus armeniaca, respectively. As shown in Figure 3(Fig. 3), SbPDS contained a conserved dinucleotide-binding motif (GXGX2GX3AX2LX3GX6EX5GG) and a carotenoid-binding domain also found in other orthologous genes (Yan et al., 2011[34]; Zhu et al., 2005[35]).

SbZDS was composed of 2159 bp, with a 1725-bp ORF encoding a protein of 574 amino acids (predicted molecular mass of 63.55 kDa; Figure 4(Fig. 4)). The closest homolog of SbZDS was ZDS from Tagetes erecta (85 % identity and 91 % similarity) followed by ZDS from Helianthus annuus (84 % identity and 91 % similarity), ZDS from Chrysanthemum x morifolium (83 % identity and 90 % similarity), and ZDS from Daucus carota (84 % identity and 91 % similarity). Similar to SbPDS, SbZDS also contained a conserved dinucleotide-binding motif at the N-terminus and a carotenoid-binding domain at the C-terminus (Figure 4(Fig. 4)).

SbCHXB consisted of 1410 bp, with a 939-bp ORF encoding a protein of 312 amino acids (predicted molecular mass of 34.48 kDa; Figure 5(Fig. 5)). SbCHXB exhibited 75 % identity and 84 % similarity with Ipomoea nil CHXB, 76 % identity and 83 % similarity with Vitis vinifera CHXB, 78 % identity and 85 % similarity with C. arabica CHXB, and 74 % identity and 82 % similarity with Lycopersicon esculentum CHXB. Four conservatively spaced histidine motifs proposed to be involved in iron binding during hydroxylation reactions are presented in Figure 5(Fig. 5) (Bouvier et al., 1998[3]).

SbZEP was composed 2399 bp, with an ORF of 1986 bp encoding a protein of 661 amino acids with a predicted molecular mass of 72.09 kDa (Figure 6(Fig. 6)). SbZEP shared 76 % identity and 84 % similarity with Solanum tuberosum ZEP, 76 % identity and 83 % similarity with N. plumbaginifolia ZEP, 76 % identity and 84 % similarity with S. lycopersicum ZEP, and 75 % identity and 84 % similarity with Ipomoea nil ZEP. SbZEP displayed 2 short motifs typical of the lipocalin family of proteins and a phosphopeptide-binding domain (FHA domain), which are likely to be the common features of ZEP genes (Durocher and Jackson, 2002[6]; Hieber et al., 2000[11]).

The expression of carotenoid biosynthetic genes was investigated in the roots, stems, leaves, and flowers of S. baicalensis by real-time PCR (Figure 7(Fig. 7)). One of the initial proteins involved in the carotenoid biosynthetic pathway, SbPSY, was expressed at the highest levels in the flowers and was found at lower levels in the leaves and stems, with the lowest expression observed in the roots. Similar to SbPSY, the expression levels of SbPDS and SbZDS were low in the roots and relatively high in the stems, leaves, and flowers. SbCHXB and SbZEP showed different transcriptional patterns with the first 3 enzymes in the carotenoid biosynthetic pathway. The mRNA transcript levels of SbCHXB and SbZEP were lowest in the leaves and higher in the roots, stems, and flowers.

The same plant materials as those used for qRT-PCR were used to analyze the composition and content of carotenoids in S. baicalensis using HPLC (Table 2(Tab. 2)). In general, carotenoids were distributed mostly in the leaves, and the majority of carotenoids detected in S. baicalensis were lutein and ß-carotene. Specifically, highly abundant lutein content (517.19 µg g^-1) was found in the leaves, whereas only a small amount of its precursor, α-carotene (2.23 µg g^-1), was found in the same organ. The leaves also contained a significant amount of ß-carotene (228.37 µg g^-1), which may explain the presence of considerable amounts of its cis isomers, 9-cis ß-carotene (21.36 µg g^-1) and 13-cis ß-carotene (29.72 µg g^-1). In contrast, accumulation of ß-carotene may cause poor accumulation of its derivatives, ß-cryptoxanthin (1.93 µg g^-1) and zeaxanthin (1.94 µg g^-1). In the stems, lutein (43.16 µg g^-1) and ß-carotene (14.08 µg g^-1) were also the major carotenoids. Only miniscule amounts of 9-cis ß-carotene (2.08 µg g^-1), 13-cis ß-carotene (1.12 µg g^-1), ß-cryptoxanthin (0.33 µg g^-1), zeaxanthin (0.85 µg g^-1), and no α-carotene were measured in the stems. The flowers accumulated lower amounts of lutein (13.18 µg g-1) and ß-carotene (6.99 µg g^-1) than the stems. Other carotenoids were either expressed at very low levels or were absent in the flowers. In the roots, only trace amounts of lutein (0.88 µg g^-1) and ß-carotene (0.35 µg g^-1) could be found.

In the present study, a partial-length cDNA encoding PSY and full-length cDNA encoding PDS, ZDS, CHXB, and ZEP were characterized, and carotenoid contents were analyzed in S. baicalensis. Carotenoid biosynthetic genes were constitutively expressed in all examined organs of S. baicalensis with different patterns between upstream genes and downstream genes. The transcription levels of SbPSY, SbPDS, and SbZDS were high in the stems, leaves, and flowers and low in the roots, while the transcription levels of SbCHXB and SbZDS were low in the leaves and relatively high in other organs. PSY, which catalyzes the first committed and rate-limiting step in carotenoid biosynthesis, is the major key regulator of carotenoid accumulation in plants (Rodríguez-Villalón et al., 2009[25]; Toledo-Ortiz et al., 2010[29]), suggesting that the low expression levels of SbPSY, SbPDS, and SbZDS caused only trace amounts of carotenoids to be found in the roots of S. baicalensis. However, SbPSY, SbPDS, and SbZDS were highly expressed in the stems and flowers, where only small amounts of carotenoids were detected. Further along in the pathway, carotenoids can be cleaved at various chain positions by carotenoid cleavage dioxygenases (CCDs) to form a broad range of apocarotenoids (Auldridge et al., 2006[2]; Huang et al., 2009[13]; Kloer and Schulz, 2006[17]). An inverse correlation between CCD expression and carotenoid content was observed in Arabidopsis (Auldridge et al., 2006[1]) and bitter melon (Tuan and Park, 2013[32]). Therefore, we hypothesize that the small amounts of carotenoids in the flowers and stems may be due to the high expression of CCDs. Further studies on CCDs in S. baicalensis are needed to clarify this hypothesis.

In the ß,ß-carotenoid branch, ß-carotene is hydroxylated by CHXB to produce zea-xanthin, which is then converted into viola-xanthin by ZEP. Low expression levels of SbCHXB and SbZEP probably result in the large accumulation of ß-carotene in the leaves of S. baicalensis. Unlike the findings for the ß,ß-carotenoid branch, in the ε,ß-carotenoid branch, lutein content was most abundant in the leaves, where its biosynthetic enzyme, SbCHXB, was expressed in low amounts. Indeed, SbCHXB has been proposed to have an active role in the flux of the ß,ß-carotenoid branch rather than the ε,ß-carotenoid branch of carotenoid biosynthesis in S. baicalensis.

Carotenoids are rarely biosynthesized in the underground organs (roots), but are very abundant in the photosynthetic organs (leaves) of S. baicalensis. This mechanism is similar to that in other plants, such as garlic (Tuan et al., 2011[30]) and bitter melon (Tuan et al., 2011[31]), and indicates the essential role of light in the accumulation of carotenoids in plants. Furthermore, we discovered that besides the roots (the most popular part of S. baicalensis), the leaves, which contain significant amounts of lutein (517.19 µg g^-1) and ß-carotene (228.37 µg g^-1), are also a potential medicinal part of this plant. For humans, lutein is believed to function as an important antioxidant and anti-inflammatory (Ma and Lin, 2010[20]; Sabour-Pickett et al., 2012[26]), and ß-carotene has been shown to have the capacity to reduce the risk of stroke, heart disease, and cancer (Kritchevsky, 1999[18]; Mayne, 1996[21]).

In conclusion, the molecular characterization of carotenoid biosynthetic genes along with carotenoid content may be useful to clarify the biosynthetic mechanisms of carotenoids in S. baicalensis in particular and in plants in general. In addition, these data will provide a foundation for the elucidation of the contribution of carotenoids to the great medicinal properties of S. baicalensis.