DOCSLIB.ORG

Lab -7- the Leaf Leaf Arrangement Leaf Tissues Dicot Leaf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Lab -7- the Leaf Leaf Arrangement Leaf Tissues Dicot Leaf First stage General plant Dr. Huda Altameme Lab -7- The Leaf A leaf is an aerial and lateral outgrowth of the stem of a usually flat and dorsiventral anatomy. It functions mainly to manufacture food by photosynthesis and consists typically of a stalk also called petiole, a flattened blade, the lamina, and the leaf base. Strands of conducting and strengthening tissues, the veins, run through it. Their pattern, also called leaf venation, is a feature of characterization. Leaves may be simple, i.e. undivided or compound (composed of several parts called leaflets). The blade margin and the leaf arrangement at the stem are further features of characterization. Simple Leaves :- Simple leaves have one leaf blade. The leaf may be irregularly shaped, but it is still one blade with one leaf stalk. Compound Leaf :- Compound leaves are made of many individual leaflets that are all attached to the same leaf stalk Modified Leaves :- Some leaves have many unusual shapes and sizes. This allows them to adapt to protect the plant, to store food, or to adapt to the environment in which they grow. Leaf Arrangement Alternate:- In an alternate arrangement, single leaves are attached spirally along the stem. Opposite:- Two leaves emerge opposite each other on a stem. Whorled:- In a whorled arrangement, several leaves emerge together around a stem node. Leaf Tissues The leaf blade’s outer surface is epidermal tissue and the ground tissue within is photosynthetic mesophyll, interspersed with “veins” (vascular bundles) of conducting (vascular) tissue. Vascular connections between blade and stem pass through the petiole. Dicot Leaf Epidermis:- There may be one or more layers of epidermal cells with cutinized outer walls that form a waterproof outer surface. Stomata of guard cells are present on the upper and lower surface or only on the lower surface. Various hairs and glands may also be present . Ground Tissue:- The parenchyma cells of the ground tissue are divided into palisade and spongy mesophyll. Usually the columnar cells of the palisade layer lie under the upper leaf epidermis and contain most of the chloroplasts of the ground tissue. The spongy parenchyma has irregular-shaped cells with air spaces between and lies above the lower leaf epidermis. Vascular Tissue:- Four small vein transections are shown which are part of the vast, interconnecting network between major veins. A leaf vein (vascular bundle) usually has xylem on the upper side and phloem on the lower side. The reverse may be true in major veins. A layer of parenchyma cells called a bundle sheath , which functions in First stage General plant Dr. Huda Altameme moving materials between the vein and the mesophyll tissue, usually encloses small veins. Monocot Leaf (Grass) Epidermis:- Along with the epidermal cells , guard cells , hairs, silica, and cork cells, grass leaves have bulliform cells . The bubble-shaped, water-filled bulliform cells control leaf rolling (when the leaf is dry) and unrolling (when the leaf is turgid or filled with water). Under drought conditions, bulliform cells collapse and the leaf rolls up. Ground Tissue:- In the temperate region, grass mesophyll consists of only spongy parenchyma tissue whose cells contain chloroplasts—sites of photosynthesis. Vascular Tissue:- Grass leaves have bundle sheaths surrounding each vein. Sclerenchyma fiber strands may be associated with the veins. Conifer Leaf Epidermis:- The usually small, triangular or flat “needle” leaves of conifers are adapted to dry conditions. Epidermal cells have thick walls of cuticle, and sunken stomatal guard cells overlapped on the surface by subsidiary cells . Stomata may be on one or all sides of the leaf surface. Under the epidermis may be a layer of thick- walled sclerenchyma cells called hypodermis . Ground Tissue. Mesophyll tissue is not usually differentiated into palisade and spongy layers. Resin ducts are present. Vascular Tissue. There are one or two veins in the center surrounded by transfusion tissue and endodermis containing tannins and resins. Practical parts: 1- Observe the characters of leaves then draw the simple , compound and modified leaves in Nerium, Rosa and Allium respectively. Nerium Rosa Allium First stage General plant Dr. Huda Altameme 2- Observe the Leaf Arrangement in stem and draw it . Alternate Opposite Whorled 3- Examine the permanent slide of Corn (Zea mays) stem in 10x magnification, Showing : cuticle, upper epidermis, mesophyll, vein (or vascular bundle), xylem, phloem, bundle sheath cells, lower epidermis, guard cells, bulliform cells. First stage General plant Dr. Huda Altameme 4- Examine the permanent slide of Helianthus or Ligustrum stem in 10x magnification. You should be able to recognize: cuticle, upper epidermis, palisade mesophyll, spongy mesophyll, vein (or vascular bundle of a leaf), xylem, phloem, bundle sheath cells, lower epidermis, guard cells. 5- Examine the permanent slide of Pinus (Conifer Leaf) in 10x magnification. You should be able to recognize: Epidermis , Stomata, Resin canal and Vascular bundle. .
Load more

Recommended publications
  • Vascular Construction and Development in the Aerial Stem of Prionium (Juncaceae) Author(S): Martin H
    Vascular Construction and Development in the Aerial Stem of Prionium (Juncaceae) Author(s): Martin H. Zimmermann and P. B. Tomlinson Source: American Journal of Botany, Vol. 55, No. 9 (Oct., 1968), pp. 1100-1109 Published by: Botanical Society of America Stable URL: http://www.jstor.org/stable/2440478 . Accessed: 19/08/2011 13:58 Your use of the JSTOR archive indicates your acceptance of the Terms & Conditions of Use, available at . http://www.jstor.org/page/info/about/policies/terms.jsp JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact [email protected]. Botanical Society of America is collaborating with JSTOR to digitize, preserve and extend access to American Journal of Botany. http://www.jstor.org Amer.J. Bot. 55(9): 1100-1109.1968. VASCULAR CONSTRUCTION AND DEVELIOPMENT IN THE AERIAL STEM OF PRIONIUM (JUNCACEAE)1 MARTIN H. ZIMMERMANN AND P. B. TOMLINSON HarvardUniversity, Cabot Foundation,Petersham, Massachusetts and FairchildTropical Garden, Miami, Florida A B S T R A C T The aerial stemof Prioniumhas been studiedby motion-pictureanalysis which permits the reliabletracing of one amonghundreds of vascularstrands throughout long series of transverse sections.By plottingthe path of many bundles in the maturestem, a quantitative,3-dimensional analysisof their distribution has beenmade, and by repeatingthis in theapical regionan under- standingof vasculardevelopment has been achieved.In the maturestem axial continuityis maintainedby a verticalbundle which branches from each leaf tracejust beforethis enters the leaf base.
    [Show full text]
  • The Vascular System of Monocotyledonous Stems Author(S): Martin H
    The Vascular System of Monocotyledonous Stems Author(s): Martin H. Zimmermann and P. B. Tomlinson Source: Botanical Gazette, Vol. 133, No. 2 (Jun., 1972), pp. 141-155 Published by: The University of Chicago Press Stable URL: http://www.jstor.org/stable/2473813 . Accessed: 30/08/2011 15:50 Your use of the JSTOR archive indicates your acceptance of the Terms & Conditions of Use, available at . http://www.jstor.org/page/info/about/policies/terms.jsp JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact [email protected]. The University of Chicago Press is collaborating with JSTOR to digitize, preserve and extend access to Botanical Gazette. http://www.jstor.org 1972] McCONNELL& STRUCKMEYER ALAR AND BORON-DEFICIENTTAGETES 141 tomato, turnip and cotton to variations in boron nutri- Further investigationson the relation of photoperiodto tion. II. Anatomical responses. BOT.GAZ. 118:53-71. the boron requirementsof plants. BOT.GAZ. 109:237-249. REED, D. J., T. C. MOORE, and J. D. ANDERSON. 1965. Plant WATANABE,R., W. CHORNEY,J. SKOK,and S. H. WENDER growth retardant B-995: a possible mode of action. 1964. Effect of boron deficiency on polyphenol produc- Science 148: 1469-1471. tion in the sunflower.Phytochemistry 3:391-393. SKOK, J. 1957. Relationships of boron nutrition to radio- ZEEVAART,J. A. D. 1966. Inhibition of stem growth and sensitivity of sunflower plants.
    [Show full text]
  • Plant Anatomy Lab 5
    Plant Anatomy Lab 7 - Stems II This exercise continues the previous lab in studying primary growth in the stem. We will be looking at stems from a number of different plant species, and emphasize (1) the variety of stem tissue patterns, (2) stele types and the location of vascular tissues, (3) the development of the stem from meristem activity, and (4) the production of xylem and phloem by the procambium. All of the species studied are pictured either in your text or the atlases at the front of the lab. 1) Early vascular plants (cryptogams) A) Obtain a piece of the rachis of the fern (collected in the White Hall atrium). This structure is superficially analogous to a stem, although it has a different origin. Prepare a transverse section of the rachis and stain it in toluidine blue. Note the large amount of cortical tissue and the presence of sclerenchyma cells near the outer cortex. Also note that the stele vascular tissue appears to be amphiphloic. Lastly, you should be able to see readily the endodermal-style thickenings on the cells just outside each vascular bundle. B) Find prepared slides of the Osmunda and Polypodium (fern) rhizomes. Note the amphiphloic bundles (a protostele?), the presence of sclerenchyma in the cortex, and the thickened walls of the endodermis that you will find is not uncommon among many non-seed plants. Remember that rhizomes are modified stems that often occur underground. Osmunda fern vascular bundle. C) Obtain a prepared slide of Psilotum. This stele does not have a pith, so it is a protostele (or an actinostele because it has a star-like shape).
    [Show full text]
  • Secondary Thickening Vascular Cambium
    nd th Plant Anatomy/ 2 class 12 lecture : Secondary thickening Secondary Thickening Any arising in plant thickness occur far away from the Apies occur as a result of secondary tissues formation & it represent secondary plant body. Secondary thickening occur in most of dicotyledonae & Gymnospermae & some of monocotyledonae as like as in Palmaceae. Secondary thickening occur as a result of 2 kinds of secondary meristematic and they are: 1- Cork cambium (explained in Periderm sub.) 2- Vascular cambium. Vascular cambium: The lateral meristem that forms the secondary vascular tissues, it is located between the xylem & phloem in the stem & root, cylinder in shape, in most petioles & leaf veins it appears as strips. Vascular cambium cells characteristic are: 1- thin cell wall plasmodesmata, dense cytoplasm, dense endoplasmic reticulum, with many rhibosomes. 2- contain (1) nucleus its size in fusiform initials larger than in ray initials. 3- cambium cells appear in radial arrangement with the cell that produce it. 4- usually divide periclinal division and sometimes divide anti linal division. Vascular cambium consist of 2 kind of cells: 1- Fusiform initials / cell: elongated cells with tapering ends (spindle – shaped). 2- Ray cell/ initials: small, isodiametric cells. 1 nd th Plant Anatomy/ 2 class 12 lecture : Secondary thickening Factors that effect on vascular cambium activity: (1)photoperiod, (2)temperature, and (3) water available. The Root The underground part of plant axis specialized as an absorbing & anchoring organ. Origin of the root is the radical which initiate from the hypocotyl of the embryo. The root functions are the absorption of water and other substances anchoring the plant in the substrate, store of vegetative reproduction.
    [Show full text]
  • Dicot/Monocot Root Anatomy the Figure Shown Below Is a Cross Section of the Herbaceous Dicot Root Ranunculus. the Vascular Tissu
    Dicot/Monocot Root Anatomy The figure shown below is a cross section of the herbaceous dicot root Ranunculus. The vascular tissue is in the very center of the root. The ground tissue surrounding the vascular cylinder is the cortex. An epidermis surrounds the entire root. The central region of vascular tissue is termed the vascular cylinder. Note that the innermost layer of the cortex is stained red. This layer is the endodermis. The endodermis was derived from the ground meristem and is properly part of the cortex. All the tissues inside the endodermis were derived from procambium. Xylem fills the very middle of the vascular cylinder and its boundary is marked by ridges and valleys. The valleys are filled with phloem, and there are as many strands of phloem as there are ridges of the xylem. Note that each phloem strand has one enormous sieve tube member. Outside of this cylinder of xylem and phloem, located immediately below the endodermis, is a region of cells called the pericycle. These cells give rise to lateral roots and are also important in secondary growth. Label the tissue layers in the following figure of the cross section of a mature Ranunculus root below. 1 The figure shown below is that of the monocot Zea mays (corn). Note the differences between this and the dicot root shown above. 2 Note the sclerenchymized endodermis and epidermis. In some monocot roots the hypodermis (exodermis) is also heavily sclerenchymized. There are numerous xylem points rather than the 3-5 (occasionally up to 7) generally found in the dicot root.
    [Show full text]
  • Branching Morphology, Vascular Bundle Arrangement and Ontogenetic Development in Leaf Insertion Zones and Ramifications of Three Arborescent Araliaceae Species
    Trees DOI 10.1007/s00468-017-1585-8 ORIGINAL ARTICLE Branching morphology, vascular bundle arrangement and ontogenetic development in leaf insertion zones and ramifications of three arborescent Araliaceae species 1,2 3 1,2,4 1,2,4 Katharina Bunk • Siegfried Fink • Thomas Speck • Tom Masselter Received: 24 January 2017 / Accepted: 3 July 2017 Ó The Author(s) 2017. This article is an open access publication Abstract the woody strands in the stem–branch attachment regions. Key message A conspicuous ‘finger-like’ branching Via high-resolution microscopy of serial thin-sections and morphology is described for three arborescent Arali- 3D reconstructions, as well as cryotome sections, aceae species with a focus on the three-dimensional anatomical analysis was carried out of the course and vascular bundle arrangement in leaf insertion and arrangement of vascular bundles through leaf insertions stem–branch attachment regions during ontogenetic and later developing ramifications, including a comparative development. analysis of the different ontogenetic stages. All three spe- Abstract The central aim of this study is to gain a deeper cies investigated present a ‘finger-like’ branching mor- understanding of the structure and development in leaf phology with variations in the number and arrangement of insertions and stem–branch attachments of the arborescent the woody strands. Thin-sectioning reveals a conspicuous Araliaceae species: Schefflera arboricola, Fatsia japonica pattern of leaf trace emergence from the main stem, pro- and Polyscias balfouriana. Therefore, the vascular bundle ceeding into the leaf and the early developing ramifica- arrangement in the leaf insertion zone and ontogenetic tions. Vascular bundle derivatives contribute to the development of the stem–branch attachment after decapi- vascular integration of leaves and axillary buds.
    [Show full text]
  • The Marattiales and Vegetative Features of the Polypodiids We Now
    VI. Ferns I: The Marattiales and Vegetative Features of the Polypodiids We now take up the ferns, order Marattiales - a group of large tropical ferns with primitive features - and subclass Polypodiidae, the leptosporangiate ferns. (See the PPG phylogeny on page 48a: Susan, Dave, and Michael, are authors.) Members of these two groups are spore-dispersed vascular plants with siphonosteles and megaphylls. A. Marattiales, an Order of Eusporangiate Ferns The Marattiales have a well-documented history. They first appear as tree ferns in the coal swamps right in there with Lepidodendron and Calamites. (They will feature in your second critical reading and writing assignment in this capacity!) The living species are prominent in some hot forests, both in tropical America and tropical Asia. They are very like the leptosporangiate ferns (Polypodiids), but they differ in having the common, primitive, thick-walled sporangium, the eusporangium, and in having a distinctive stele and root structure. 1. Living Plants Go with your TA to the greenhouse to view the potted Angiopteris. The largest of the Marattiales, mature Angiopteris plants bear fronds up to 30 feet in length! a.These plants, like all ferns, have megaphylls. These megaphylls are divided into leaflets called pinnae, which are often divided even further. The feather-like design of these leaves is common among the ferns, suggesting that ferns have some sort of narrow definition to the kinds of leaf design they can evolve. b. The leaflets are borne on stem-like axes called rachises, which, as you can see, have swollen bases on some of the plants in the lab.
    [Show full text]
  • Pith Vascular Bundle
    PITH VASCULAR BUNDLE VB C.S. VASCULAR BUNDLE SIPHONOSTELE VB EUSTELE + VASCULAR BUNDLES XYLEM & PHLOEM STRAND SIPHONOSTELE EUSTELE VASCULAR BUNDLES PITH VASCULAR BUNDLE X C.S. PITH VASCULAR BUNDLE XYLEM P C.S. PITH VASCULAR BUNDLE XYLEM S PHLOEM C.S. SIPHONOSTELE PITH VASCULAR BUNDLE XYLEM E PHLOEM C.S. SIPHONOSTELE / EUSTELE PITH VASCULAR BUNDLE XYLEM ^ PHLOEM C.S. A ATACTOSTELE ATACTOSTELE VASCULAR STELE ST ATACTOSTELE SCATTERED VASCULAR BUNDLES VASCULAR STELE ATACTOSTELE TYPICAL TRACHEOPHYTE STEM VASCULAR STELE ATACTOSTELE VASCULAR EPIDERMIS BUNDLE STEM C.S. CORTEX = PHLOEM ATACTOSTELE = XYLEM STEM C.S. A VASCULAR BUNDLE STEM C.S. ^ ATACTOSTELE > TRACHEOPHYTE STELE TYPES SUMMARY P PHLOEM XYLEM C.S. H PHLOEM XYLEM PROTOSTELE ^ PHLOEM XYLEM PROTOSTELE / HAPLOSTELE P XYLEM PHLOEM C.S. A XYLEM PHLOEM PROTOSTELE ^ XYLEM PHLOEM PROTOSTELE / ACTINOSTELE P XYLEM PHLOEM C.S. P XYLEM PHLOEM PROTOSTELE ^ XYLEM PHLOEM PROTOSTELE / PLECTOSTELE S XYLEM PHLOEM PITH C.S. E XYLEM PHLOEM PITH SIPHONOSTELE ^ XYLEM PHLOEM PITH SIPHONOSTELE / ECTOPHLOIC S PITH C.S. PITH SIPHONOSTELE PITH VASCULAR TISSUE SIPHONOSTELE PITH A PHLOEM INSIDE XYLEM PHLOEM OUTSIDE SIPHONOSTELE PITH ^ PHLOEM INSIDE XYLEM PHLOEM OUTSIDE SIPHONOSTELE / AMPHIPHLOIC S PITH C.S. + PITH SIPHONOSTELE SIPHONOSTELE E PITH VASCULAR BUNDLE C.S. SIPHONOSTELE / EUSTELE ^ PITH VASCULAR BUNDLE C.S. A VASCULAR BUNDLE C.S. > ATACTOSTELE > RESPONSIBLE STELE TYPES LECTURE & LABORATORY ^ RESPONSIBLE STELE TYPES GENERAL & SPECIFIC ^ XYLEM MATURATION L PRIMARY XYLEM MATURATION PRIMARY XYLEM MATURATION PROTOXYLEM PRIMARY XYLEM MATURATION PRIMARY XYLEM P MATURATION PROTOXYLEM METAXYLEM PRIMARY XYLEM MATURATION PROTOXYLEM PRIMARY XYLEM PROTOXYLEM MATURES FIRST/BEFORE METAXYLEM PRIMARY XYLEM PROTOXYLEM P PRIMARY XYLEM ROOT C.S. ^ M PROTOXYLEM PROTOXYLEM MATURES FIRST RED = MATURE PRIMARY XYLEM ROOT C.S.
    [Show full text]
  • Environmental Factors Influence Plant Vascular System and Water
    plants Review Environmental Factors Influence Plant Vascular System and Water Regulation Mirwais M. Qaderi 1,2,* , Ashley B. Martel 2 and Sage L. Dixon 1 1 Department of Biology, Mount Saint Vincent University, 166 Bedford Highway, Halifax, NS B3M 2J6, Canada; [email protected] 2 Department of Biology, Saint Mary’s University, 923 Robie Street, Halifax, NS B3H 3C3, Canada; [email protected] * Correspondence: [email protected] Received: 9 January 2019; Accepted: 11 March 2019; Published: 15 March 2019 Abstract: Developmental initiation of plant vascular tissue, including xylem and phloem, from the vascular cambium depends on environmental factors, such as temperature and precipitation. Proper formation of vascular tissue is critical for the transpiration stream, along with photosynthesis as a whole. While effects of individual environmental factors on the transpiration stream are well studied, interactive effects of multiple stress factors are underrepresented. As expected, climate change will result in plants experiencing multiple co-occurring environmental stress factors, which require further studies. Also, the effects of the main climate change components (carbon dioxide, temperature, and drought) on vascular cambium are not well understood. This review aims at synthesizing current knowledge regarding the effects of the main climate change components on the initiation and differentiation of vascular cambium, the transpiration stream, and photosynthesis. We predict that combined environmental factors will result in increased diameter and density of xylem vessels or tracheids in the absence of water stress. However, drought may decrease the density of xylem vessels or tracheids. All interactive combinations are expected to increase vascular cell wall thickness, and therefore increase carbon allocation to these tissues.
    [Show full text]
  • Vascular Morphology of Stipe and Rachis in Some Western Himalayan
    Proc. Indian Acad. Sci. (Plant Sci.), Vol. 100, No. 6, December 1990, pp. 399-407. 9 Printed in India. Vascular morphology of stipe and raehis in some western Himalayan species of Pteris Linn. N PUNETHA Department of Botany, Government PG College, Pithoragarh 262 501, India MS received 25 June 1990; revised 10 December 1990 Abstraet. Vascularsupply to leaf in 8 species of the fern genus Pteris is described. Except in Pteris cretica in which the stipe is supplied by a pair of ribbon like vascular bundles, stipe vasculature of the other 7 species studied is solitary and gutter-shaped; in transection the vascular bundle in Pteris cretica, Pteris dactylina and Pterts stenophylla is V-shaped, ~- shaped in Pteris wallichiana and horse-shoe shaped in others. In Pteris vittata and Pteris wallichiana pinna trace is extra marginal in origin while in all others it is marginal. Based on number and structure of vascular strand and nature of origin of pinna traces it is concluded that Pteris crelica and Pteris oittata are relatively advanced over other species with simply pinnate fronds. Pteris wallichiana has been considered as highly evolved among the species investigated. Keywords. Adaxial xylem plate; leaf vasculature; fl-shaped vascular bundle; pinna trace; Pteris. 1. Introduction Leaf vasculature in ferns is to a larger extent related with the morphotogy of the frond and it has also been considered as of significance in fern taxonomy (Ogura 1972; Lin and De Vol 1977). In addition to main vascular supply to frond, the primary pinna traces are also of taxonomic significance (Bower 1926).
    [Show full text]
  • Orchestration of Three Transporters and Distinct Vascular Structures in Node for Intervascular Transfer of Silicon in Rice
    Orchestration of three transporters and distinct vascular structures in node for intervascular transfer of silicon in rice Naoki Yamajia,1, Gen Sakuraib,1, Namiki Mitani-Uenoa, and Jian Feng Maa,2 aInstitute of Plant Science and Resources, Okayama University, Kurashiki 710-0046, Japan; and bEcosystem Informatics Division, National Institute for Agro-Environmental Sciences, Tsukuba 305-8604, Japan Edited by Maarten J. Chrispeels, University of California, San Diego, La Jolla, CA, and approved July 27, 2015 (received for review May 7, 2015) Requirement of mineral elements in different plant tissues is not After EVB phase, the VB is continued to a VB of the leaf asso- often consistent with their transpiration rate; therefore, plants ciating the node (2–4). As an exception, DVBs in the uppermost have developed systems for preferential distribution of mineral two nodes (nodes I and II), in which VBs have no corresponding elements to the developing tissues with low transpiration. Here leaves, become VBs in the panicle without EVB phase as detailed we took silicon (Si) as an example and revealed an efficient system in ref. 2. Based on these repetitive vascular constructions, inter- for preferential distribution of Si in the node of rice (Oryza sativa). vascular transfers between axial VBs are required for preferential Rice is able to accumulate more than 10% Si of the dry weight in delivery of nutrients to apical tissues such as developing leaf or the husk, which is required for protecting the grains from water panicle (2). Furthermore, the node also shows distinct structures at loss and pathogen infection. However, it has been unknown for a cellular and subcellular level, which are characterized by (i)ex- long time how this hyperaccumulation is achieved.
    [Show full text]
  • Leaf Anatomy of Vetiver Grass Supporting the Potentially C Sequestration
    Leaf Anatomy of Vetiver Grass Supporting the Potentially C Sequestration 1S.Thammathaworn, and 2P. Khnema 1Nong Khai Campus, Khon Kaen University, Muang District, Nong Khai, 43000, Thailand 2 Department of Biology, Faculty of Science, Mahasarakham University, Khamriang Subdistrict, Kantharawichai District, Mahasarakham 44150, Thailand Abstract Investigation of internal leaf structures can give a primary explanation of the potentially C sequestration of the plant. This research aimed to descript internal leaf structures of 11 vetiver provenances and observe some relative structures. The results found that all 11 provenances had a similar pattern of vascular bundle arrangement with the ratio of 1:3:1:3:1 for large:small:medium:small:large and Kranz structure which is similar to C4 plants. Like aquatic plants, large lysigenous intercellular spaces in vetiver leaves strongly related aeration system. Evident of aerenchyma at cortex layer could confirm gas circulation from leaves to roots and encouraged deeply root penetration of vetiver by avoiding hypoxia condition. Moreover, “Humidity-induced convection” and “Venturi-induced convection” were assumed as a strategy to gain more gas circulation of vetiver. Especially, fiber (sclerenchyma) in bundle caps of Loei provenance extended from abaxial to adaxial surface believed playing a dual function of mechanic and hydraulic (a short cut of water pathways) which could retain stomata open and longer gas exchange. Angle of leaf wings reflected an adaptive high radiation and was useful for provenance classification. In conclusion, the internal leaf structures attributed all 11 vetiver provenances to sequester more C and especially Loei provenance. Keywords: Kranz structure, lysigenous intercellular space, arenchyma, vascular bundle. Introduction Investigating internal leaf structures can predict efficiency of C assimilation, photosynthetic mechanisms, environment during the plant grown and subsequently potentially C sequestration.
    [Show full text]