1. Introduction
Heliotropium L. related to Heliotropiaceae Schrad., which was included in Boraginaceae Juss. It considered paraphyletic taxon [1] [2] . Now Heliotropiaceae deals as a separate family [3] . Heliotropium is selected for its importance and strong resemblances on the morphological characters. The infrageneric classification of Heliotropium into sections has been a debatable matter. Recently, Olwey [4] mentioned this genus divided into Section Heliotropium, Section Orthostachys, Section Pleurolasia, Section Pseudocoelomae, Section Pterotropium, Section Ruditotheca and Section Zeylanica. There are 10 species of genus Heliotropium distributed in Jazan of Saudi Arabia [5] [6] . Distribution and forms of trichomes are important qualities to be used to differentiate between the different genera and species of plant [7] . Leaf epidermal characters are useful in systematic phylogeny of several plant taxa and can be employed as useful taxonomic characters in segregating the major groups of plants [8] - [10] . [11] investigated leaf anatomy and distribution of foliar trichrome of four Heliotropium species which have been investigated in Saudi Arabia. On the other hand, [12] carried out a comparison between the anatomical leaves and stems structure of five species of genus Heliotropium in Sudan. [13] reported the occurrence of tricolpate pollen grain in H. vellosum and H. indicum. Genus Heliotropium is characterized by its striking similarity on morphological characters, so this study aims to evaluate the systematic relationships of their similarity and dissimilarity compared to the modern findings of taxonomic relationships of species within the genus.
2. Materials and Methods
Fresh samples of the seven species of the genus Heliotropium were collected from different localities of Jazan. The plant specimens were identified according to [5] [6] Ten sample epidermal strips were removed from lower surface of the leaves were; these were fixed in 20% glycerine. The slides were examined under the light microscope at 40×. Various anatomical features, such as number and type of stomata, length and width of stomata, trichomes form and types were studied. The size of stomata and hair were recorded with the help of a calibrated eyepiece. The stomatal index (S.I.) was calculated using the formula adopted from [14] that is:

where S is the number of stomata per unit of area, and E the number of epidermal cells in the same area. Pollen grains from fresh plants were collected on a slide and acetolyzed according to the method of [13] . Acetolyzed pollen grains were photographed by light microscope. For anatomical studies, stem cross sections were done using freshly-collected material or material fixed in ethanol, this material was cut free hand or in a semi rotative microtome to make semi-permanent and permanent slides for the microscopic slides, carried out according to the usual Johansen’s methods [15] .
3. Results and Discussion
3.1. Leaf and Inflorescence Morphology
Some distinctive characters such as inflorescence length, leaf shape and venation have been studied and summarized in Table 1.
According to the terminology of [16] [17] , there are two types of venation found: Hyphodromous and Brochidodromous.
3.2. Stomatal Behavior
The qualitative and quantitative leaf epidermal features of the taxa and their frequency of stomatal indexes are presented in Table 2 and Figure 1. Amphistomatic stomata are common in all the studied taxa. Their ranunculus distributed on the adaxial and the abaxial surface of the leaves. The stomatal length, width and frequency also varied. The maximum stomatal length and pore size were observed in H. petrocarpum (19 mm) followed by H. strigosium being 17 mm and the minimum stomata length was found in H. zeylanicum (7 mm) followed by H. longiflorium (9 mm). Three types of stomata were recognized; anomocytic type is common in the tree species: H. petrocarpum, H. strigosium and H. zeylanicum. Paracytic type was found only in H. arbainense. Anisocytic types were noticed in H. longiflorum and H. lasiocarpum. Stomatal index differed between the taxa, where the highest value of 44.87% was calculated for H. jizanense while the lowest index (28.57%) was noticed in H. longiflorum.
3.3. Epidermal Trichromes
Unicellular epidermal trichromes have been watched on both the surface of stem and leaves. Also, glandular
(a) (b) (c)
(d) (e) (f)
(g)
Figure 1. Photographical images of epidermal cells showing the stomata types (x = 400). (a) H. arbainense (anisocytic); (b) H. longiflorium (paracytic); (c) H. petrocarpum (anomocytic); (d) H. strigosium (anomocytic); (e) H. zeylanicum (anomocytic); (f) H. jizanense (anisocytic); (g) H. lasiocarpum (anisocytic).
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Table 1. Leaf and inflorescence measurements between the studied species.
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Table 2. Stomata measurements and stomata indices for the species.
hairs were found in all the seven studied taxa. Basal hair form and vestibule differed between the taxa where hollow appeared in H. arbainense, H. peterocarpum and H. jizanense. Spindle hair form was found only in H. longicarpum; density, type, basal cell and their walls are presented in Table 3 and photographed in Figure 2.
Densely hairy with filled basal cells was found in H. lasiocarpum, H. strigosum and H. zeylanicum hairs with rough walls.
3.4. Pollen Grain Characters
Pollen grains types form and different measurements are recorded in Table 4. Tricolpate pollen grains types were noticed in all the species (Figure 3). Oval form was found in H. longiflorum. Circular was found in
(a) (b) (c)
(d) (e) (f)
(g)
Figure 2. Light microscopic images (X = 100) showing hollow and filled vestibule basal hair in the studied species. (a) H. arbainense; (b) H. longiflorium (paracytic); (c) H. petrocarpum; (d) H. strigosium; (e) H. zeylanicum; (f) H. jizanense; (g) H. lasiocarpum.
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Table 3. Hair leaves measurements for the seven studied species.
(a) (b) (c)
(d) (e) (f)
(g)
Figure 3. Equatorial view by light microscopic images (X = 1000) of oval form in H. longiflorum, rectangula in H. arbainense and H. petrocarpum, elliptical in H. strigosium, rounded in H. zeylanicum and triangular in H. jizanense
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Table 4. Pollen grain measurements for the seven studied species.
H. arbainense and H. petrocarpum. Elliptical form was noticed in H. strigosium. Rounded form was recorded in H. zeylanicum, and also triangular was noticed in H. jizanense. The pollen length and aperture size also varied between the taxa. The maximum pollen length and width (P/E) of 1.81 µm were recorded in H. longiflorum followed by 1.68 found in H. strigosium. The lowest P/E was noticed in H. arbainense (0.70 µm).
3.5. Stem Anatomical Data
Stem anatomical characters and their measurements between the studied species are recorded in Table 5 and stem photographs are listed in Figure 4. Epidermis in all species consists in a single layer. All taxa except H. pterocarpum have two layers of cubical or rounded cells covering with trichromes. Hairs and other epidermal outgrowths have been noticed in all species; the hypodermis consists of elongated chlorenchyma cells in H.
(a) (b) (c)
(d) (e) (f)
(g)
Figure 4. Light microscopic micrograph (X = 100). (a) H. arbainense; (b) H. longiflorium; (c) H. petrocarpum; (d) H. strigosium; (e) H. zeylanicum; (f) H. jizanense; (g) H. lasiocarpum.
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Table 5. Anatomical measurements between the studied species.
arbainense, H. pterocarpum and H. zeylanicum. Two layers of chlorenchyma cells were observed in H. longiflorum and H. strigosium. Three layers of parenchyma cells were found only in H. jizanense. The cortex was found in angular with 4 - 5 layers of collenchyma cells which were present in H. arbainense and H. jizanense. 5 - 6 layers of lacunar collenchyma cells were found in H. strigosium. A normal collenchyma cell was found in H. longiflorum, H. petrocarpum and H. zeylanicum. Vascular strands in all the taxa studied are separated by parenchymatous cells which are smaller in size than cortex or pith. Vessels are scattered and clustered into two groups in H. arbainense and H. petrocarpum or three groups in H. longiflorum, H. strigosium, H. zeylanicum and H. jizanense. In the old stem sections continuous ring of fascicular and iterfascicular cambium has been observed in all the studied species. Primary phloem appears as a dark staining mass in H. longiflorium and H. strigosium. Wood vessels are scattered and clustered into two groups in H. arbainense and H. petrocarpum or three groups in H. longiflorum, H. zeylanicum and H. jizanense. In general, leaf venation varied between the species, brochidodromous noticed in H. arbainense and H. lasiocarpum while the remainders have hyphodromous type. Such results are similar to report of [3] . It is obvious that, the stomatal index varied between the studied species in turn in accordance with the results of [18] . Apart from hairs, emergences and glandular hairs have been noted previously by different authors. Glandular hairs with multicellular stalk have been observed in all the seven species. Hairs vary from species to other which in turn indicated at significant taxonomic data; basal hair form appeared hollow in H. arbainense, H. peterocarpum and H. jizanense. Spindle shape was found only in H. longiflorum with rough hair wall which differed from the previous studies. Also, pollen grains indicated good taxonomic data which differed in form and pollen apertures. Such results are in agreement with [19] . Also, the pollen length and apertures size also varied between the taxa studied. H. longiflorum has distinct anatomical data which support data obtaining pollen grains in which colporate pollen aperture is P/E (1.8 µm) in addition to presence of hair spindle form. The hypodermis showed variation and accordingly H. zeylanicum was separated from the other studied species having 2 layers of chlorenchyma cells whereas the remainders species have 1 - 2 layers of parenchyma cells. Vessel forms, number and wood porous differed between the taxa. Wood porous found in all taxa except H. strogosium has unporous xylem form. Such results differed with results of [12] . On the other hand, H. longiflorum is characterized by distinctive data which in turn can be separated as a taxonomic level; the following key shows the possibility of using both the previous characters for identification of the studied Heliotropium species:
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