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. 2014 Nov 12;22(2):181–185. doi: 10.1016/j.sjbs.2014.11.002

Biodiversity characteristics of Teucrium polium species in Saudi Arabia

Najat A Bukhari 1,, Reem A Al-Otaibi 1, Mohammed M Ibhrahim 1
PMCID: PMC4336436  PMID: 25737650

Abstract

Teucrium (Lamiaceae) is a large and polymorphic genus distributed mainly in Europe, North Africa and in the temperate parts of Asia. In this study, the anatomical features of the leaf and stem of Teucrium polium are investigated. Teucrium has 19 taxa in Iran, which mainly grow in the Irano-Turanian region between 700 and 2000 m above sea level. T. polium belonging to sect. Polium, is a perennial herb growing on Lorestan province. The leaves clearly exhibit xeromorphy due to features such as thick cuticle layer, thick outer epidermal cell wall, high density of trichomes and thick palisade layer of the mesophyll. Anatomical studies on T. polium revealed that the stem shares the general characteristics of the Labiatae family. The aim of our approach was to study the morphological and taxonomical parameters for T. polium in Saudi Arabia. The results of this study showed that there was no influence of environment on the structure of stomata and trichomes as studying species with T.polium. In conclusion our study shows we have studied the geographical distribution of the species in Saudi Arabia and in the world.

Keywords: Teucrium polium, Teucrium (Lamiaceae), Saudi Arabia

1. Introduction

The genus Teucrium L., with about 100 species, is a large genus distributed in Europe, North Africa, and temperate parts of Asia, but mainly in the Mediterranean region (Mabberley, 1997) along with the genera Stachys L. (Akçiçek, 2010) and Sideritis L. (Guvenc and Duman, 2010). Teucrium has 19 taxa in Iran, which mainly grow in the Irano-Turanian region between 700 and 2000 m above sea level (Rechinger, 1982). The basic sectional arrangement of the genus is based mainly on the calyx and inflorescence types with varying characteristics (Abdollahi et al., 2003). Among them Teucrium persicum Boiss is the only one endemic to Iran (Rechinger, 1982). Teucrium species are distributed in most regions of Iran i.e. T. persicum is present only at elevations of southern regions as a Saharo-Sinidian element, while T. hyrcanicum L., which is a hyrcanian element, grows in the north of Iran. Some species, namely Teucrium polium L. and T. orientale L., are widely distributed in steppe, arid, and semiarid regions (Eshratifar et al., 2011). Saudi Arabia possesses a unique genetic diversity in the form of ecotypes of tree species. The western and southwestern regions of the country are rich in native plant flora of cultivated crops and medicinal plants (Anonymous, 1970). Around 300 species of medicinal plants are used in traditional medicine in Saudi Arabia. The rural population depends to a greater extent on wild plants for medicines. Traditional medicine in Saudi Arabia is based on herbal remedies and spiritual healing. Herbal medicine regulation in Saudi Arabia was undertaken in 1996 with the issue of a separate law specifically for herbal medicines.

The aim of the present investigation was to study the morphological and taxonomical parameters of T. polium species in Saudi Arabia and also to evaluate the variations in the concentrations and distributions of some secondary metabolites and also to determine the antioxidant and free radical scavenging activity.

2. Materials and methods

Plants were collected from samples of different herbariums. These herbariums are from King Saud University (KSU), King Abdul-Aziz University (KAU), King Abdul-Aziz city for science and technology (KACST), National Commission for Wild Life Conservation and Development (NCWCD) and Ministry of Water (RIY) or collected from different localities of Saudi Arabia.

2.1. Study of morphological characters

  • (1)

    Description of morphological and floral characters.

  • (2)

    Measurements of the whole plant.

  • (3)

    Measurement of leaf area.

  • (4)

    Measurement of sepals (calyx) and petals (corolla).

2.2. Study of stomata and trichomes on leaf surface (micro morphology)

Leaves are collected from plant samples of different herbariums.

Dried adult leaves are cut into a fragment of 1 cm (West, 1968) in the middle of the lamina and put into a test tube which contains 10% of nitric acid (HNO3). The test tube was placed in a water bath at 100 °C for 5–10 min. After cooling the fragment was then transferred into a Petri dish filled with distilled water. Both halves of the cuticular membrane were gently brushed to clean them from any remaining pieces of the mesophyll tissue. The fragment was then placed into a watch glass filled with 5% acetic acid for 30 min. To bleach, the fragment was washed with distilled water and transferred into 50% alcohol for 2 min, alcin blue for 5 min, alcoholic series (50%, 70%, 80%, 90% and 100%) for 2 min in each series and finally in 1:1 solution of absolute alcohol and Histo clear for 2 min and then in Histo clear for 3 s. After dehydration, the fragment was transferred onto a slide greased with Histo clear and mounted with Canada balsam. The leaf’s stomata sculpturing and trichomes were studied with Light Microscope Olympus (CX41RF), and photographed with camera mounted on light microscope (V-TV063XC).

Four species were scanned using Scanning Electron Microscope (SEM). Young leaves (first fully expanded leaf from the tip) and old leaves (third or fourth fully expanded leaf from the tip) were collected from each plant. Plant specimens for SEM using procedures described by McWhorter et al. (1993). Squares of leaves (with approx. 1 mm thickness of underlying tissues) were excised from the plant, using a razor blade, avoiding the midrib areas so as to give a relatively consistent surface. Leaf segments of approximately 20 mm were fixed for 12 h in 4% glutaraldehyde and rinsed three times with distilled water before dehydration in a graded ethanol series. Samples were dried in a critical point drier and were mounted on aluminum stubs using two-sided adhesive carbon tape. The samples were then coated with a thin layer of gold. Scanning was performed in an electron microscope (Jeol JSM 6060) LV. Electron images were recorded using a digital image processor.

3. Results and discussion

3.1. Duration and habitat

Canescent fleecy herbs perennial or annual, white, tomentose or soft and somewhat low, highly aromatic dwarf shrublet, branched from the base with numerous erect, ascending or spreading, according to Daoud (1985), Al-Kahtani et al. (2000), Shalby et al. (1985), Mandaville (1990),Migahid (1996) and Collenette (1999) (Table 1).

Table 1.

Duration, habitat and morphological characters of stem of Teucrium polium species in Saudi Arabia.

Species Characters
Duration Habitat Stem
Orientation Defince
Perennial Annual Herb Shrub Shrublet Twining Prostrate Erect Climb Glabrous Tomentose Canescent Pubescent Woody
Teucrium polium + + + - + - - + - - + + - -
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3.2. Stem

Stems are rigid, branched at base, with soft spreading hairs 10–40 cm long, as stated by Batanouny (1981), Mandaville (1990) and Migahid (1996) (Plate 1).

3.3. Leaves

Leaves are sessile and simple, oblong-linear, spatulate, crenate margin and obtuse apex, opposite blade, shorter than flowers 10–15 mm long , 3–5 mm wide, crenulated at least in upper half, strongly revolute. They are of tomentose surface similar to that reported in Daoud (1985) Mandaville (1990) and Al-Kahtani et al. (2000) (Table 2).

Table 2.

Morphological characteristics of leaves of Teucrium polium species in Saudi Arabia.

Species Characters
Blade
 Arrangement
 Leaf surface
 Attachments
Apex shape
 Shape
 Margin
Obtuse Acute Triangular– ovate Oblong– linear Elliptical Spatulate Linear-lanceolate Rolled Entire Crenate Alternate Opposite Scabrid hairy Tomentose Glabrous Petiolate Sessile
Teucrium polium + + + + + + +
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3.4. Inflorescences and flowers

Flower bisexual, inflorescences terminal and corymbose, or sub terminal and axillary; racemose or head–like, flowers 1-many in axillary verticillate cymes or terminal racemes flowers many together in dense spherical to ovate, short peduncled terminal heads: bracts linear-spatulate , shorter than flowers, sessile c. 12–15 mm in diameter in flat heads that become cone shaped with age; aromatic , calyx c. 4 mm tubular-campanulate, equally deeply 5-lobed, sub sessile, white-tomentose, teeth 5, triangular, tube, locoes, ovate, acute or obtuse teeth which are all nearly equal and about half as long as the tube, corolla deciduous, blue or white, 5-lobed, usually included, naked to densely beared within, limb bilabiate but upper lip very short, lower lip conspicuous and spreading , with small lateral lobes, white, or cream, woolly, somewhat longer than calyx c. 7–8 mm long very pale pinkish, yellowish in throat, stamens 4 fertile, didynamous inserted near apex of corolla tube, hardly exerted anthers bilocular, cells divergent or divaricate at maturity, scarcely exerted, style bifid, stigmas 2-lobed, according to Batanouny (1981), Daoud (1985), Shalby et al. (1985), Mandaville (1990), Migahid (1996), Collenette (1999) and Al-Kahtani et al. (2000) (Table 3) and Plates 1 and 2.

Table 3.

Floral characteristics of Teucrium polium species in Saudi Arabia.

Species Characters
Inflorescence
 Flower
 Calyx Corolla
Type
 Flower attachment
 Unisexual
 Bisexual
 Shape
 Color
Axillary Solitary Terminal Corymbose Racemose Pedicellate Sessile Lanceolate Campanulate Oblong-ovate Yellow Deeply lobed Yellow White Blue pink
Teucrium polium + + + + + + + + +
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T. polium (Labiatae) is a wild growing flowering plant and is found in south western Asia (KSA) and Europe. The study of morphology is reported by Mooney and Parsons (1973), Parsons (1976), (Fahn (1988), Christodoulakis and Bazos (1990), Christodoulakis and Fasseas (1991), Fahn and Cutler (1992), Ascensão et al. (1999), Corsi and Bottega (1999), Sacchetti et al. (1999), El Oualidi et al. (2002).

It is used in Iranian folk medicine for treating many diseases such as abdominal pain, indigestion, common cold, diabetes, and urogenital diseases and this plant has been reported to have hypolipidemic, antinociceptive and anti-inflammatory (Rasekh et al., 2001; Esmaeili and Yazdanparast, 2004; Abdollahi et al., 2003; Tariq et al., 1989, effects. T. polium has been reported for its relatively safe nature as medicinal herb (Starakis et al., 2006). All Teucrium species are considered as potential source of diterpenoidal compounds (Avula et al., 2003; Bruno et al., 1989; Bruno et al., 2002; Hassan et al., 1979). Anti-cancer chemo sensitizer effects of unique diterpenoids were reported by several researchers Corea et al. (2004), Michaelis et al. (2000), Shalinsky et al. (1993). In a previous communication, hepatotoxicity associated with the hypoglycemic effects of T. polium or polygermander was reported and the literature on this herb was extensively reviewed (Zal et al., 2001). It is available in essential oils, pharmaceutical properties, and the effects of herbal remedies containing T. polium and Teucrium. capitatum (Starakis et al., 2006; Ardestani et al., 2008; Sharififar et al., 2009; Dourakis et al., 2002).

Species belonging to the genus Teucrium have been shown to contain different classes of compounds such as fatty acid esters, diterpenes, monoterpenes, sesquiterpenes, flavonoids and polyphenolics (Fonta et al., 1999; Mini et al., 1991; Cozzani et al., 2005; Harborne et al., 1986; Rizk et al., 1986; Uma et al., 2000).

Flavonoids that have been isolated from T. polium species include cirsimaritin, cirsiliol, cirsilineol, 5-hydroxy-6,7,3′,4′-tetramethoxyflavone, salvigenin, apigenin 5-galloylglucoside, apigenin-7-glucoside, vicenin-2- and luteolin-7-glucoside (Esmaeili et al., 2004; Harborne et al., 1986; Kadifkova et al., 2005). The antioxidant potential of cirsimaritin and apigenin-7-glucoside has been indicated (Cuvelier et al., 1994).

Polyphenolic compounds have also shown strong antioxidant activity (Kadifkova et al., 2005), the positive effects of these antioxidant components come from their ability to inhibit lipid peroxidation and chelate redox-active metals (Marchand, 2002). There is evidence that flavonoids have anti-phosphodiesterase activity and could thus elevate intracellular levels of cyclic nucleotides (Abdollahi et al., 2003).

It is considered to be of great pharmaceutical importance and most were referred and used for medical purposes since the ancient times. Dioscorides (77 AD), traditionally used in folk medicine: febrifuge, stomachic, vermifuge. Infusion of tender parts is used in stomach and intestinal troubles. The plant is also used in steam bath to treat cold and fever (Mossa et al., 2000).

This study provides a chemotaxonomic significance of the studied plant species collected from various catchment areas in Saudi Arabia on the basis of evidence from morphometric and phytochemical studies. Our study concludes that, we have studied the geographical distribution of the species in Saudi Arabia and in the world.

Acknowledgements

This research project was supported by a grant from the Research Center of the Female Scientific and Medical colleges, Deanship of Scientific Research, King Saud University.

Footnotes

Peer review under responsibility of King Saud University.

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