DOCSLIB.ORG

STRUCTURE of PLANTS and FUNGI Edited By: Zoltán Kristóf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
STRUCTURE of PLANTS and FUNGI Edited By: Zoltán Kristóf STRUCTURE OF PLANTS AND FUNGI Edited by: Zoltán Kristóf Pál Vági Éva Preininger Gábor M. Kovács Zoltán Kristóf Károly Bóka Béla Böddi XML to PDF by RenderX XEP XSL-FO F ormatter, visit us at http://www.renderx.com/ STRUCTURE OF PLANTS AND FUNGI: Edited by: Zoltán Kristóf by Pál Vági, Éva Preininger, Gábor M. Kovács, Zoltán Kristóf, Károly Bóka, and Béla Böddi Copyright © 2013 Eötvös Loránd University This book is freely available for research and educational purposes. Reproduction in any form is prohibited without written permission of the owner. Made in the project entitled "E-learning scientific content development in ELTE TTK" with number TÁMOP-4.1.2.A/1-11/1-2011-0073. Consortium leader: Eötvös Loránd University, Consortium Members: ELTE Faculties of Science Student Foundation, ITStudy Hungary Ltd. XML to PDF by RenderX XEP XSL-FO F ormatter, visit us at http://www.renderx.com/ Table of Contents 1. INTRODUCTION ..................................................................................................................... 1 1.1. Organization levels ........................................................................................................... 1 1.2. Autotrophy and body structure ............................................................................................ 2 1.3. The role of water .............................................................................................................. 2 1.4. The transport process and the possibility of regulation on organism level .................................... 3 1.5. Specialities of plant secretion ............................................................................................. 3 1.6. Morphological and anatomical polarity of plants .................................................................... 4 1.7. Stem cells and cell plasticity in plants .................................................................................. 4 1.8. The anatomical and physiological role of storage ................................................................... 5 1.9. Basic rules of plant reproduction ......................................................................................... 5 1.10. Alternation of generations in the plant kingdom .................................................................... 6 1.11. Genetic interpretation of the alternation phases .................................................................... 6 2. MORPHOLOGY ....................................................................................................................... 8 2.1. Seed and seedling ............................................................................................................. 8 2.2. Root .............................................................................................................................. 9 2.3. Stem ............................................................................................................................ 12 2.4. Buds ............................................................................................................................ 13 2.5. Leaf ............................................................................................................................. 14 2.6. Flower, inflorescence ...................................................................................................... 17 2.7. Fruit ............................................................................................................................. 21 3. CYTOLOGY .......................................................................................................................... 23 3.1. Characteristics of the plant cell .......................................................................................... 23 3.2. The cell wall .................................................................................................................. 23 3.3. The vacuolar system ........................................................................................................ 26 3.4. Plastids ......................................................................................................................... 27 3.5. Cell division .................................................................................................................. 29 3.5.1. Mitosis ............................................................................................................... 30 3.5.2. Meiosis .............................................................................................................. 31 4. PLANT TISSUES .................................................................................................................... 33 4.1. Meristems ..................................................................................................................... 33 4.1.1. Classification of meristems according to their origin ................................................... 33 4.1.2. Classification of meristems according to position ....................................................... 34 4.1.3. Classification of meristems according to the cell division plane ..................................... 34 4.2. Dermal tissue system ....................................................................................................... 34 4.2.1. Epidermis ........................................................................................................... 34 4.2.2. Rhizodermis ........................................................................................................ 37 4.2.3. Secondary and tertiary dermal tissues ....................................................................... 37 4.3. Ground tissue system ...................................................................................................... 38 4.3.1. Parenchyma ........................................................................................................ 38 4.3.2. Supporting or mechanical ground tissues .................................................................. 38 4.4. Vascular tissue system ..................................................................................................... 40 4.4.1. Xylem ................................................................................................................ 40 4.4.2. Phloem .............................................................................................................. 41 4.4.3. Vascular bundles .................................................................................................. 42 4.4.4. Different types of stele .......................................................................................... 43 5. PLANT ORGANS (ORGANOGRAPHY) .................................................................................... 45 5.1. Root ............................................................................................................................. 45 5.1.1. Longitudinal zonation pattern of the root .................................................................. 45 5.1.2. Primary tissues of the root ..................................................................................... 45 5.1.3. Secondary thickening of the root ............................................................................. 47 5.2. Stem ............................................................................................................................ 47 5.2.1. Primary tissues of the stem ..................................................................................... 48 5.2.2. Secondary thickening of the stem ............................................................................ 48 5.3. Secondary xylem (wood) ................................................................................................. 50 5.4. Leaf ............................................................................................................................. 51 iii XML to PDF by RenderX XEP XSL-FO F ormatter, visit us at http://www.renderx.com/ STRUCTURE OF PLANTS AND FUNGI 5.4.1. Ontogeny of the leaf ............................................................................................. 51 5.4.2. Leaf anatomy ...................................................................................................... 52 5.4.3. Leaf and environment ........................................................................................... 53 5.4.4. Abscission .......................................................................................................... 54 6. Anatomy and reproduction of lower plants .................................................................................... 55 6.1. Mosses ......................................................................................................................... 55 6.1.1. Hornworts (Anthocerophyta) .................................................................................. 55 6.1.2. Liverworts (Hepatophyta) ...................................................................................... 56 6.1.3. Peat mosses (Sphagnopsida) ................................................................................... 58 6.1.4. Granite mosses (Andreaeopsida) ............................................................................. 60 6.1.5. True mosses (Bryopsida) ....................................................................................... 61 6.2. Pteridophytes ................................................................................................................
Load more

Recommended publications
  • CATALOGUE of the GRASSES of CUBA by A. S. Hitchcock
    CATALOGUE OF THE GRASSES OF CUBA By A. S. Hitchcock. INTRODUCTION. The following list of Cuban grasses is based primarily upon the collections at the Estaci6n Central Agron6mica de Cuba, situated at Santiago de las Vegas, a suburb of Habana. The herbarium includes the collections made by the members of the staff, particularly Mr. C. F. Baker, formerly head of the department of botany, and also the Sauvalle Herbarium deposited by the Habana Academy of Sciences, These specimens were examined by the writer during a short stay upon the island in the spring of 1906, and were later kindly loaned by the station authorities for a more critical study at Washington. The Sauvalle Herbarium contains a fairly complete set of the grasses col- lected by Charles Wright, the most important collection thus far obtained from Cuba. In addition to the collections at the Cuba Experiment Station, the National Herbarium furnished important material for study, including collections made by A. H. Curtiss, W. Palmer and J. H. Riley, A. Taylor (from the Isle of Pines), S. M. Tracy, Brother Leon (De la Salle College, Habana), and the writer. The earlier collections of Wright were sent to Grisebach for study. These were reported upon by Grisebach in his work entitled "Cata- logus Plant arum Cubensium," published in 1866, though preliminary reports appeared earlier in the two parts of Plantae Wrightianae. * During the spring of 1907 I had the opportunity of examining the grasses in the herbarium of Grisebach in Gottingen.6 In the present article I have, with few exceptions, accounted for the grasses listed by Grisebach in his catalogue of Cuban plants, and have appended a list of these with references to the pages in the body of this article upon which the species are considered.
    [Show full text]
  • Pharmacognosy 1
    PHARMACOGNOSY 1 Dr. Dima MUHAMMAD 0 References: 1. Trease and Evans Pharmacognosy, William C. Evans, Saunders Elsevier, 2009, sixteenth ed., ISBN 978-0 -7020 -2934 9 2. textbook of pharmacognosy & phytochemistry, Biren Shah & A.K. Seth, Elsevier, 2010, 1st ed, ISBN: 978-81-312-2298-0 3. Medicinal Natural Products: A Biosynthetic Approach. Paul M Dewick, John Wiley & Sons, 2009,3rd Edition, ISBN 978-0-470-74168-9. 4. Martins, A., Vieira, H., Gaspar, H., & Santos, S. (2014). Marketed Marine Natural Products in the Pharmaceutical and Cosmeceutical Industries: Tips for Success. Marine Drugs, 12(2) 1 1. MEANING OF PHARMACOGNOSY Pharmacognosy, known initially as materia medica, may be defined as the study of crude drugs obtained from plants, animals and mineral kingdom and their constituents. There is a historical misinformation about who created the term pharmacognosy. According to some sources, it was C. A. Seydler, a medical student at Halle, Germany, in 1815; he wrote his doctoral thesis titled Analectica Pharmacognostica. However, recent historical research has found an earlier usage of this term. The physician J. A. Schmidt (Vienna) used that one in his Lehrbuch der materia medica in 1811, to describe the study of medicinal plants and their properties. The word pharmacognosy is derived from two Latin words pharmakon, ‘a drug,’ and gignoso, ‘to acquire knowledge of’. It means ‘knowledge or science of drugs. Crude drugs are plants or animals, or their parts which after collection are subjected only to drying or making them into transverse or longitudinal slices or peeling them in some cases. Most of the crude drugs used in medicine are obtained from plants, and only a small number comes from animal and mineral kingdoms.
    [Show full text]
  • Development and Cell Cycle Activity of the Root Apical Meristem in the Fern Ceratopteris Richardii
    G C A T T A C G G C A T genes Article Development and Cell Cycle Activity of the Root Apical Meristem in the Fern Ceratopteris richardii Alejandro Aragón-Raygoza 1,2 , Alejandra Vasco 3, Ikram Blilou 4, Luis Herrera-Estrella 2,5 and Alfredo Cruz-Ramírez 1,* 1 Molecular and Developmental Complexity Group at Unidad de Genómica Avanzada, Laboratorio Nacional de Genómica para la Biodiversidad, Cinvestav Sede Irapuato, Km. 9.6 Libramiento Norte Carretera, Irapuato-León, Irapuato 36821, Guanajuato, Mexico; [email protected] 2 Metabolic Engineering Group, Unidad de Genómica Avanzada, Laboratorio Nacional de Genómica para la Biodiversidad, Cinvestav Sede Irapuato, Km. 9.6 Libramiento Norte Carretera, Irapuato-León, Irapuato 36821, Guanajuato, Mexico; [email protected] 3 Botanical Research Institute of Texas (BRIT), Fort Worth, TX 76107-3400, USA; [email protected] 4 Laboratory of Plant Cell and Developmental Biology, Division of Biological and Environmental Sciences and Engineering (BESE), King Abdullah University of Science and Technology (KAUST), Thuwal 23955-6900, Saudi Arabia; [email protected] 5 Institute of Genomics for Crop Abiotic Stress Tolerance, Department of Plant and Soil Science, Texas Tech University, Lubbock, TX 79409, USA * Correspondence: [email protected] Received: 27 October 2020; Accepted: 26 November 2020; Published: 4 December 2020 Abstract: Ferns are a representative clade in plant evolution although underestimated in the genomic era. Ceratopteris richardii is an emergent model for developmental processes in ferns, yet a complete scheme of the different growth stages is necessary. Here, we present a developmental analysis, at the tissue and cellular levels, of the first shoot-borne root of Ceratopteris.
    [Show full text]
  • The Revised Classification of Eukaryotes
    See discussions, stats, and author profiles for this publication at: https://www.researchgate.net/publication/231610049 The Revised Classification of Eukaryotes Article in Journal of Eukaryotic Microbiology · September 2012 DOI: 10.1111/j.1550-7408.2012.00644.x · Source: PubMed CITATIONS READS 961 2,825 25 authors, including: Sina M Adl Alastair Simpson University of Saskatchewan Dalhousie University 118 PUBLICATIONS 8,522 CITATIONS 264 PUBLICATIONS 10,739 CITATIONS SEE PROFILE SEE PROFILE Christopher E Lane David Bass University of Rhode Island Natural History Museum, London 82 PUBLICATIONS 6,233 CITATIONS 464 PUBLICATIONS 7,765 CITATIONS SEE PROFILE SEE PROFILE Some of the authors of this publication are also working on these related projects: Biodiversity and ecology of soil taste amoeba View project Predator control of diversity View project All content following this page was uploaded by Smirnov Alexey on 25 October 2017. The user has requested enhancement of the downloaded file. The Journal of Published by the International Society of Eukaryotic Microbiology Protistologists J. Eukaryot. Microbiol., 59(5), 2012 pp. 429–493 © 2012 The Author(s) Journal of Eukaryotic Microbiology © 2012 International Society of Protistologists DOI: 10.1111/j.1550-7408.2012.00644.x The Revised Classification of Eukaryotes SINA M. ADL,a,b ALASTAIR G. B. SIMPSON,b CHRISTOPHER E. LANE,c JULIUS LUKESˇ,d DAVID BASS,e SAMUEL S. BOWSER,f MATTHEW W. BROWN,g FABIEN BURKI,h MICAH DUNTHORN,i VLADIMIR HAMPL,j AARON HEISS,b MONA HOPPENRATH,k ENRIQUE LARA,l LINE LE GALL,m DENIS H. LYNN,n,1 HILARY MCMANUS,o EDWARD A. D.
    [Show full text]
  • Poaceae: Pooideae) Based on Plastid and Nuclear DNA Sequences
    d i v e r s i t y , p h y l o g e n y , a n d e v o l u t i o n i n t h e monocotyledons e d i t e d b y s e b e r g , p e t e r s e n , b a r f o d & d a v i s a a r h u s u n i v e r s i t y p r e s s , d e n m a r k , 2 0 1 0 Phylogenetics of Stipeae (Poaceae: Pooideae) Based on Plastid and Nuclear DNA Sequences Konstantin Romaschenko,1 Paul M. Peterson,2 Robert J. Soreng,2 Núria Garcia-Jacas,3 and Alfonso Susanna3 1M. G. Kholodny Institute of Botany, Tereshchenkovska 2, 01601 Kiev, Ukraine 2Smithsonian Institution, Department of Botany MRC-166, National Museum of Natural History, P.O. Box 37012, Washington, District of Columbia 20013-7012 USA. 3Laboratory of Molecular Systematics, Botanic Institute of Barcelona (CSIC-ICUB), Pg. del Migdia, s.n., E08038 Barcelona, Spain Author for correspondence ([email protected]) Abstract—The Stipeae tribe is a group of 400−600 grass species of worldwide distribution that are currently placed in 21 genera. The ‘needlegrasses’ are char- acterized by having single-flowered spikelets and stout, terminally-awned lem- mas. We conducted a molecular phylogenetic study of the Stipeae (including all genera except Anemanthele) using a total of 94 species (nine species were used as outgroups) based on five plastid DNA regions (trnK-5’matK, matK, trnHGUG-psbA, trnL5’-trnF, and ndhF) and a single nuclear DNA region (ITS).
    [Show full text]
  • Septal Pore Caps in Basidiomycetes Composition and Ultrastructure
    Septal Pore Caps in Basidiomycetes Composition and Ultrastructure Septal Pore Caps in Basidiomycetes Composition and Ultrastructure Septumporie-kappen in Basidiomyceten Samenstelling en Ultrastructuur (met een samenvatting in het Nederlands) Proefschrift ter verkrijging van de graad van doctor aan de Universiteit Utrecht op gezag van de rector magnificus, prof.dr. J.C. Stoof, ingevolge het besluit van het college voor promoties in het openbaar te verdedigen op maandag 17 december 2007 des middags te 16.15 uur door Kenneth Gregory Anthony van Driel geboren op 31 oktober 1975 te Terneuzen Promotoren: Prof. dr. A.J. Verkleij Prof. dr. H.A.B. Wösten Co-promotoren: Dr. T. Boekhout Dr. W.H. Müller voor mijn ouders Cover design by Danny Nooren. Scanning electron micrographs of septal pore caps of Rhizoctonia solani made by Wally Müller. Printed at Ponsen & Looijen b.v., Wageningen, The Netherlands. ISBN 978-90-6464-191-6 CONTENTS Chapter 1 General Introduction 9 Chapter 2 Septal Pore Complex Morphology in the Agaricomycotina 27 (Basidiomycota) with Emphasis on the Cantharellales and Hymenochaetales Chapter 3 Laser Microdissection of Fungal Septa as Visualized by 63 Scanning Electron Microscopy Chapter 4 Enrichment of Perforate Septal Pore Caps from the 79 Basidiomycetous Fungus Rhizoctonia solani by Combined Use of French Press, Isopycnic Centrifugation, and Triton X-100 Chapter 5 SPC18, a Novel Septal Pore Cap Protein of Rhizoctonia 95 solani Residing in Septal Pore Caps and Pore-plugs Chapter 6 Summary and General Discussion 113 Samenvatting 123 Nawoord 129 List of Publications 131 Curriculum vitae 133 Chapter 1 General Introduction Kenneth G.A. van Driel*, Arend F.
    [Show full text]
  • Prof. DA Agboola: BOT221: Seedless Plants/Cryptogamic Botany 1
    Prof. D.A. Agboola: BOT221: Seedless Plants/Cryptogamic Botany CRYPTOGAMS - Flowerless or seedless plants - Lower and more primitive plants - 3 main groups i.e. Thallophyte, Bryophyte and Pteridophyte - Thallophytes include: Algae, fungi, Bacteria and lichens - Bryophytes include liverworts, horned liverworts and mosses - Pteridophytes include ferns and their allies. Reproduction - Members may take one or more of 3 methods of reproduction including vegetative, asexual and sexual - Vegetative by cell division or fragmentation - Asexual is through production of various types of spores - Sexual takes place by fusion of two gametes - Degree of sexuality passes through progressive stages including isogamy, anisogany to oogamy - Isogamy takes place in primitive cryptogams where two gametes of similar shape, size and behavior (isogametes) occurs - In anisogamy the two gametes, may be slightly different in size and behavior (Anisogametes) - In advanced cryptogams the two gametes become differentiated into male i.e. microgametes or antherozoids as spermatozoa and the female i.e. megagametes, the egg cell or oosphere or ovum - The egg cell is housed in structures including oogonium - The antherozoids are housed in antheridium - In oogamous cryptogams, the male gamete is usually small, ciliated or flagellated, active and initiative - The egg cell in large, non-motile, non ciliated, passive and receptive - Alternation of generation occurs in higher algae, liverworts, mosses, ferns and related pteridophyte - Here, life history is completed in two alternative stages or generations - These two generations differ in both morphological characteristics and mode of reproduction - One generation i.e. the sporophytic generation or asexual generation reproduces asexually by means of spores - While the other generation, i.e.
    [Show full text]
  • On the Taxonomic Position of Panicum Scabridum (Poaceae, Panicoideae, Paspaleae)
    Phytotaxa 163 (1): 001–015 ISSN 1179-3155 (print edition) www.mapress.com/phytotaxa/ Article PHYTOTAXA Copyright © 2014 Magnolia Press ISSN 1179-3163 (online edition) http://dx.doi.org/10.11646/phytotaxa.163.1.1 On the taxonomic position of Panicum scabridum (Poaceae, Panicoideae, Paspaleae) M. AMALIA SCATAGLINI1,2, SANDRA ALISCIONI1 & FERNANDO O. ZULOAGA1 1Instituto de Botánica Darwinion, Labardén 200, Casilla de Correo 22, B1642HYD, San Isidro, Buenos Aires, Argentina. 2Author for correspondence: [email protected] Abstract Panicum scabridum, an incertae sedis species of Panicum s.l., is here included in the genus Coleataenia, following a phylogenetic analysis based on one new ndhF sequence of the species and associated morphological data. Panicum scabridum and species of Coleataenia are cespitose and perennial plants, with a lower glume (1–)3–5-nerved, 1/3 to 3/4 of the spikelet, upper glume and lower lemma 5–9-nerved, and upper anthecium smooth, shiny, and indurate. Within Coleataenia, P. scabridum appeared as the sister taxon of the species pair C. prionitis and C. petersonii; these three species are the only NADP-me taxa of tribe Paspaleae exhibiting two bundle sheaths around the vascular bundles, i.e., with an outer parenchymatous sheath and an inner mestome sheath with specialized chloroplasts. The new combination Coleataenia scabrida is proposed and a lectotype is designated. Key words: Panicum scabridum, phylogeny, combined analysis, anatomy Introduction Panicum scabridum Döll (1877: 201), originally described from a specimen collected in Brazil, grows in Colombia, Venezuela and the Guianas to northern Brazil and Bolivia, in wet open places at low elevations.
    [Show full text]
  • Principles of Plant Taxonomy. Ix.*
    PRINCIPLES OF PLANT TAXONOMY. IX.* JOHN H. SCHAFFNER. In the eighth paperf of the present series, a general synopsis of the Thallophyta was given, together with a diagramatic "tree" of relationships of the orders recognized. Since the fungi are of special importance and are thus often studied independently of other groups and since the true fungi evolved a distinctive type of plant body and cell constitution, the following analysis is presented as a partial explanation of the arrangement of the groups in the synopsis. Special attention has been given to the development of correct interpretations of life histories in the light of special studies on the problem of sex in plants in general as well as comparative studies of life cycles. THE FOUR GENERAL TYPES OF FUNGI. If we use the term Fungi to include all Thallophytes without chlorophyll, then these plants fall into at least four distinctive, fundamental groups or great phyla. The various kinds of bacteria, including the slime bacteria (Myxobacteriales), show a very profound segregation from the remaining groups and are closely associated with the blue-green algae in the Schizophyta. The saprophytic slime-molds constitute a very 'distinct phylum of their own, whose nearest relatives are probably to be found among the Rhizopoda of the animal kingdom on the one hand and among the Archemycetae on the other, especially the Plasmodiophorales. But they are, nevertheless, so widely divergent from either of these groups that they are best con- sidered as a distinct phylum which has evolved along its own lines from a very primitive starting point.
    [Show full text]
  • U Tech Glossary
    URGLOSSARY used without permission revised the Ides of March 2014 glos·sa·ry Pronunciation: primarystressglässchwaremacron, -ri also primarystressglodots- Function: noun Inflected Form(s): -es Etymology: Medieval Latin glossarium, from Latin glossa difficult word requiring explanation + -arium -ary : a collection of textual glosses <an edition of Shakespeare with a good glossary> or of terms limited to a special area of knowledge <a glossary of technical terms> or usage <a glossary of dialectal words> Merriam Webster Unabridged tangent, adj. and n. [ad. L. tangens, tangent-em, pr. pple. of tangĕre to touch; used by Th. Fincke, 1583, as n. in sense = L. līnea tangens tangent or touching line. In F. tangent, -e adj., tangente n. (Geom.), Ger. tangente n.] c. In general use, chiefly fig. from b, esp. in phrases (off) at, in, upon a tangent, ie off or away with sudden divergence, from the course or direction previously followed; abruptly from one course of action, subject, thought, etc, to another. (http://dictionary.oed.com) As in off on a tangent. “Practice, repetition, and repetition of the repeated with ever increasing intensity are…the way.” Zen in the Art of Archery by Eugen Herrigel. For many terms, this glossary contains definitions from multiple sources, each with their own nuance, each authors variation emphasized. Reading the repeated definitions, with their slight variations, helps create a fuller, more overall understanding of the meaning of these terms. The etymology of the entries reinforces and may repeat the repetitions. Wax on, wax off. Sand da floor. For sometime, when I encounter a term I don’t understand (and there are very many), I have been looking them up in the oed and copying the definition into a Word document.
    [Show full text]
  • Data Standards Version 2.8 July 5
    Euro+Med Data Standards Version 2.8. July 5th, 2002 EURO+MED PLANTBASE PREPARATION OF THE INITIAL CHECKLIST: DATA STANDARDS VERSION 2.8 JULY 5TH, 2002 This document replaces Version 2.7, dated May 16th, 2002 Compiled for the Euro+Med PlantBase Editorial Committee by: Euro+Med PlantBase Secretariat, Centre for Plant Diversity and Systematics, School of Plant Sciences, The University of Reading, Whiteknights, Reading RG6 6AS United Kingdom Tel: +44 (0)118 9318160 Fax: +44 (0)118 975 3676 E-mail: [email protected] 1 Euro+Med Data Standards Version 2.8. July 5th, 2002 Modifications made in Version 2.0 (24/11/00) 1. Section 2.4 as been corrected to note that geography should be added for hybrids as well as species and subspecies. 2. Section 3 (Standard Floras) has been modified to reflect the presently accepted list. This may be subject to further modification as the project proceeds. 3. Section 4 (Family Blocks) – genera have been listed where this clarifies the circumscription of blocks. 4. Section 5 (Accented Characters) – now included in the document with examples. 5. Section 6 (Geographical Standard) – Macedonia (Mc) is now listed as Former Yugoslav Republic of Macedonia. Modification made in Version 2.1 (10/01/01) Page 26: Liliaceae in Block 21 has been corrected to Lilaeaceae. Modifications made in Version 2.2 (4/5/01) Geographical Standards. Changes made as discussed at Palermo General meeting (Executive Committee): Treatment of Belgium and Luxembourg as separate areas Shetland not Zetland Moldova not Moldavia Czech Republic
    [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]