Plant Taxonomy Table

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COMMON AND LATIN NAMES OF IMPORTANT PLANT TAXA LATIN NAME* COMMON NAME Abies Fir Acer Maple Acer negundo Box elder Aesculus Buckeye; Horse Chestnut Alnus Alder Ambrosia Ragweed Apiaceae [Umbelliferae] Carrot or parsley family Artemisia Sagebrush; sage; wormwood Asteraceae [Compositae] Aster or Sunflower Family Betula Birch Boraginaceae Borage family Brassicaceae [Cruciferae} Mustard family Caryophyllaceae Pinks Castanea Chestnut Compositae (Asteraceae) Aster or Sunflower family Cornus Dogwood Corylus Filbert; hazelnut Cruciferae (Brassicaceae) Mustard family Cupressaceae Junipers, cypresses, "cedars", others Cyperaceae Sedge family Ericaceae Heath family Fabaceae [Leguminosae] Pea family Fagus Beech Fraxinus Ash Gramineae (Poaceae) Grass family Juglans Walnut; butternut Labiatae (Lamiaceae) Mint family Larix Larch; tamarack Leguminosae (Fabaceae) Pea family Liliaceae Lily family Liriodendron Tulip tree or yellow poplar Nuphar Water lily Onagraceae Evening primrose family Papaveraceae Poppy family Picea Spruce Pinus Pine Plantago Plantain Poaceae [Gramineae] Grass family Polemonium Jacob's ladder Polygonaceae Buckwheat family Populus Poplar; cottonwood; aspen Potamogeton Pondweed Primulaceae Primrose family Quercus Oak Ranunculaceae Buttercup family Rosaceae Rose family Rhus sumac, incl. poison ivy, etc. Salix Willow Saxifragaceae Saxifrage family Scrophulariaceae Snapdragon family Sparganium Bur reed Thalictrum Meadow rue Tilia Linden or basswood Tsuga Hemlock Typha Cattail Ulmus Elm Umbelliferae (Apiaceae) Carrot or parsley family * Names of genera are always italicized; family names are given in Roman characters. All proper plant family name ends in -aceae; family names above that don't have this ending are old names, and the proper modern name is included in parentheses. .

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(Cruciferae) – Mustard Family
BRASSICACEAE (CRUCIFERAE) – MUSTARD FAMILY Plant: herbs mostly, annual to perennial, sometimes shrubs; sap sometimes peppery Stem: Root: Leaves: mostly simple but sometimes pinnately divided; alternate, rarely opposite or whorled; no stipules Flowers: mostly perfect, mostly regular (actinomorphic); 4 sepals, 4 petals often forming a cross; 6 stamens with usually 2 outer ones shorter than the inner 4; ovary superior, mostly 2 fused carpels, 1 to many ovules, 1 pistil Fruit: seed pods, often used in classification, many are slender and long (Silique), some broad (Silicle) – see morphology slide Other: a large family, many garden plants such as turnip, radish, and cabbage, also some spices; often termed the Cruciferae family; Dicotyledons Group Genera: 350+ genera; 40+ locally WARNING – family descriptions are only a layman’s guide and should not be used as definitive Flower Morphology in the Brassicaceae (Mustard Family) - flower with 4 sepals, 4 petals (often like a cross, sometimes split or lobed), commonly small, often white or yellow, distinctive fruiting structures often important for ID 2 types of fruiting pods: in addition, fruits may be circular, flattened or angled in cross-section Silicle - (usually <2.5x long as wide), 2-valved with septum (replum) Silique - (usually >2.5x long as wide), 2- valved with septum (replum) Flowers, Many Genera BRASSICACEAE (CRUCIFERAE) – MUSTARD FAMILY Sanddune [Western] Wallflower; Erysimum capitatum (Douglas ex Hook.) Greene var. capitatum Wormseed Wallflower [Mustard]; Erysimum cheiranthoides L. (Introduced) Spreading Wallflower [Treacle Mustard]; Erysimum repandum L. (Introduced) Dame’s Rocket [Dame’s Violet]; Hesperis matronalis L. (Introduced) Purple [Violet] Rocket; Iodanthus pinnatifidus (Michx.) Steud. Michaux's Gladecress; Leavenworthia uniflora (Michx.) Britton [Cow; Field] Cress [Peppergrass]; Lepidium campestre L.) Ait.
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Family Fabaceae
CATNIP classes, Acme Botanical Services 2013 Fabaceae (Pea Family, Bean Family, Legume Family) The third largest family of angiosperms (behind the aster family (Asteraceae) and the orchid family (Orchidaceae), the Fabaceae includes somewhere between 16.000 and 20,000 species. It rivals the grass family (Poaceae) in terms of economic importance. The Fabaceae includes plants of all growth forms, from trees and shrubs down to annual and perennial herbs. Members are easy to recognize on the basis of the foliage, which involves compound leaves of various kinds; the flowers, which are of three types (see subfamilies below); and the fruit, which is a single-chambered dry pod. Three subfamilies are recognized. All three are well represented in the Capital area. Mimosoideae. In this subfamily, the leaves are twice-pinnately compound. The flowers are tightly packed into heads or spikes. The flowers are regular (radially symmetrical), but the perianth (corolla and calyx) is so tiny as to be scarcely noticeable. The stamens are the conspicuous part of the flower, usually numerous and 10 times or more as long as the corolla. In many species, such as Nuttall’s sensitive- briar (Mimosa nuttallii, right), the flower heads resemble pink pom-poms. Caesalpinoideae. Plants of this group have even-pinnate or odd-pinnate leaves. The flowers have a conspicuous corolla with 5 separate petals. The stamens are separate and visible (i.e., not concealed by the corolla. Most of the species in our area have yellow petals. Roemer’s two-leaf senna (Senna roemeriana, right) is typical. Papilionideae. This is the largest subfamily in our area, and the one with the bilaterally symmetrical two-lipped flowers that come to mind any time the pea family is mentioned.
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Pollination of Rapeseed (Brassica Napus) by Africanized Honeybees (Hymenoptera: Apidae) on Two Sowing Dates
Anais da Academia Brasileira de Ciências (2014) 86(4): 2087-2100 (Annals of the Brazilian Academy of Sciences) Printed version ISSN 0001-3765 / Online version ISSN 1678-2690 http://dx.doi.org/10.1590/0001-3765201420140134 www.scielo.br/aabc Pollination of Rapeseed (Brassica napus) by Africanized Honeybees (Hymenoptera: Apidae) on Two Sowing Dates EMERSON D. CHAMBÓ1, NEWTON T.E. DE OLIVEIRA1, REGINA C. GARCIA1, JOSÉ B. DUARTE-JÚNIOR1, MARIA CLAUDIA C. RUVOLO-TAKASUSUKI2 and VAGNER A. TOLEDO3 1Universidade Estadual do Oeste do Paraná, Campus Universitário de Marechal Cândido Rondon, Centro de Ciências Agrárias, Rua Pernambuco, 1777, 85960-000 Marechal Cândido Rondon, PR, Brasil 2Universidade Estadual de Maringá, Centro de Ciências Biológicas, Departamento de Biotecnologia, Genética e Biologia Celular, Av. Colombo, 5790, Jardim Universitário, 87020-900 Maringá, PR, Brasil 3Programa de Pós-Graduação em Zootecnia, Universidade Estadual de Maringá, Centro de Ciências Agrárias, Av. Colombo, 5790, Bloco J45, Campus Universitário 87020-900 Maringá, PR, Brasil Manuscript received on January 21, 2014; accepted for publication on June 23, 2014 ABSTRACT In this study, performed in the western part of the state of Paraná, Brazil, two self-fertile hybrid commercial rapeseed genotypes were evaluated for yield components and physiological quality using three pollination tests and spanning two sowing dates. The treatments consisted of combinations of two rapeseed genotypes (Hyola 61 and Hyola 433), three pollination tests (uncovered area, covered area without insects and covered area containing a single colony of Africanized Apis mellifera honeybees) and two sowing dates (May 25th, 2011 and June 25th, 2011). The presence of Africanized honeybees during flowering time increased the productivity of the rapeseed.
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Invasive Asteraceae Copy.Indd
Family Asteraceae Family: Asteraceae Spotted Knapweed Centaurea biebersteinii DC. Synonyms Acosta maculosa auct. non Holub, Centaurea maculosa auct. non Lam. Related Species Russian Knapweed Acroptilon repens (L.) DC. Description Spotted knapweed is a biennial to short-lived perennial plant. Seedling cotyledons are ovate, with the first leaves lance-shaped, undivided, and hairless. (Young seedlings can appear grass-like.) Stems grow 1 to 4 feet tall, and are many-branched, with a single flower at the end of each branch. Rosette leaves are indented or divided Old XID Services photo by Richard about half-way to the midrib. Stem leaves are alternate, pinnately divided, Spotted knapweed flower. and get increasingly smaller toward the tip of each branch. Flower heads are urn-shaped, up to 1 inch wide, and composed of pink, purple, or sometimes white disk flowers. A key characteristic of spotted knap- weed is the dark comb-like fringe on the tips of the bracts, found just below the flower petals. These dark-tipped bracts give this plant its “spotted” appearance. Russian knapweed is a creeping perennial plant that is extensively branched, with solitary urn-shaped pink or purple flower heads at the end of each branch. Similar in appearance to spotted knapweed, Russian knapweed can be distinguished by its slightly smaller flower heads, flower head bracts covered in light hairs, with papery tips, and scaly dark brown or black rhizomes, which have a burnt appearance. Family: Asteraceae Spotted Knapweed Leaves and stems of both spotted and Russian knapweeds are covered in fine hairs, giving the plants a grayish cast.
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The Developmental and Genetic Bases of Apetaly in Bocconia Frutescens
Arango‑Ocampo et al. EvoDevo (2016) 7:16 DOI 10.1186/s13227-016-0054-6 EvoDevo RESEARCH Open Access The developmental and genetic bases of apetaly in Bocconia frutescens (Chelidonieae: Papaveraceae) Cristina Arango‑Ocampo1, Favio González2, Juan Fernando Alzate3 and Natalia Pabón‑Mora1* Abstract Background: Bocconia and Macleaya are the only genera of the poppy family (Papaveraceae) lacking petals; how‑ ever, the developmental and genetic processes underlying such evolutionary shift have not yet been studied. Results: We studied floral development in two species of petal-less poppies Bocconia frutescens and Macleaya cordata as well as in the closely related petal-bearing Stylophorum diphyllum. We generated a floral transcriptome of B. frutescens to identify MADS-box ABCE floral organ identity genes expressed during early floral development. We performed phylogenetic analyses of these genes across Ranunculales as well as RT-PCR and qRT-PCR to assess loci- specific expression patterns. We found that petal-to-stamen homeosis in petal-less poppies occurs through distinct developmental pathways. Transcriptomic analyses of B. frutescens floral buds showed that homologs of all MADS-box genes are expressed except for the APETALA3-3 ortholog. Species-specific duplications of other ABCE genes inB. frute- scens have resulted in functional copies with expanded expression patterns than those predicted by the model. Conclusions: Petal loss in B. frutescens is likely associated with the lack of expression of AP3-3 and an expanded expression of AGAMOUS. The genetic basis of petal identity is conserved in Ranunculaceae and Papaveraceae although they have different number of AP3 paralogs and exhibit dissimilar floral groundplans.
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Section 4 Oilseed Rape (Brassica Napus L.)
SECTION 4 OILSEED RAPE (BRASSICA NAPUS L.) 1. General Information This consensus document addresses the biology of the species Brassica napus L. Included are general descriptions of this species as a crop plant, its origin as a species, its reproductive biology, its centres of origin, and its general ecology. The ecology of this species is not described in relation to specific geographic regions. Special emphasis has been placed on detailing potential hybridisation between B. napus and its close relatives, although this discussion is limited to hybridisation events which do not require intervention through means such as embryo rescue (i.e. these events could possibly occur in nature, and could result in fertile offspring). This document was prepared by a lead country, Canada. It is based on material developed in OECD Member countries – for example, for risk assessments or for presentation at conferences and scientific meetings. It is intended for use by regulatory authorities and others who have responsibility for assessments of transgenic plants proposed for commercialisation, and by those who are actively involved in these plants’ design and development. The table in the Appendix showing potential interactions of B. napus with other life forms during its life cycle was developed with respect to Canada. As such, it is intended to serve as an example. Member countries are encouraged to develop tables showing interacting organisms specific to their own geographic regions and environments. 2. General Description and Use as a Crop Brassica napus L. is a member of the subtribe Brassicinae of the tribe Brassiceae of the Cruciferous (Brassicaceae) family, sometimes referred to as the mustard family.
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Agronomic Performance of Brassicaceae Oilseeds in Multiple Environments Across the Western USA
BioEnergy Research (2019) 12:509–523 https://doi.org/10.1007/s12155-019-09998-1 Agronomic Performance of Brassicaceae Oilseeds in Multiple Environments Across the Western USA Russ W. Gesch1 & D. S. Long2 & D. Palmquist3 & B. L. Allen4 & D. W. Archer5 & J. Brown6 & J. B. Davis6 & J. L. Hatfield7 & J. D. Jabro4 & J. R. Kiniry8 & M. F. Vigil9 & E. A. Oblath3 & T. A. Isbell3 Published online: 2 July 2019 # This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply 2019 Abstract Brassicaceae oilseed crops can provide rotation benefits to dryland wheat (Triticum aestivum L.) and supply feedstock for biofuel production. However, growers face decisions about what oilseed crop is best suited for an environment. The objective of this study was to determine how varying production environments affect the agronomic performance of modern cultivars of six Brassicaceae crop species and identify ideal genotypes for seven growing environments spanning four ecoregions. A field experiment was replicated in Colorado, Idaho, Iowa, Minnesota, Montana, North Dakota, and Oregon, USA, between 2013 and 2016 to measure seed and oil yields of seed for four cultivars of Brassica napus,twoofB. carinata,twoofB. juncea,twoof Sinapis alba,oneofB. rapa, and one of Camelina sativa.Also,δ13C signature of seed was used as an indicator of water limitation. Generally, across all genotypes, seed and oil yields increased with increased growing season precipitation. Modern commercial cultivars of B. napus and B. juncea had the highest seed oil contents and generally produced the greatest oil yields across most environments, although they were not always the highest seed yielders.
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The Plant Family Brassicaceae ENVIRONMENTAL POLLUTION
The Plant Family Brassicaceae ENVIRONMENTAL POLLUTION VOLUME 21 Editors Brain J. Alloway, Department of Soil Science, The University of Reading, U.K. Jack T. Trevors, School of Environmental Sciences, University of Guelph, Ontario, Canada Editorial Board I. Colbeck, Interdisciplinary Centre for Environment and Society, Department of Biological Sciences, University of Essex, Colchester, U.K. R.L. Crawford, Food Research Center (FRC) 204, University of Idaho, Moscow, Idaho, U.S.A. W. Salomons, GKSS Research Center, Geesthacht, Germany For further volumes: http://www.springer.com/series/5929 Naser A. Anjum l Iqbal Ahmad M. Eduarda Pereira l Armando C. Duarte Shahid Umar l Nafees A. Khan Editors The Plant Family Brassicaceae Contribution Towards Phytoremediation Editors Naser A. Anjum Iqbal Ahmad Centre for Environmental and Centre for Environmental and Marine Marine Studies (CESAM) & Studies (CESAM) & Department Department of Chemistry of Chemistry and Biology University of Aveiro University of Aveiro 3810-193 Aveiro 3810-193 Aveiro Portugal Portugal M. Eduarda Pereira Armando C. Duarte Centre for Environmental and Centre for Environmental and Marine Studies (CESAM) & Marine Studies (CESAM) & Department of Chemistry Department of Chemistry University of Aveiro University of Aveiro 3810-193 Aveiro 3810-193 Aveiro Portugal Portugal Shahid Umar Nafees A. Khan Department of Botany Department of Botany Faculty of Science Faculty of Life Sciences Hamdard University Aligarh Muslim University New Delhi, 110062 Aligarh 202002 India Uttar Pradesh, India ISSN 1566-0745 ISBN 978-94-007-3912-3 ISBN 978-94-007-3913-0 (eBook) DOI 10.1007/978-94-007-3913-0 Springer Dordrecht Heidelberg New York London Library of Congress Control Number: 2012936075 # Springer Science+Business Media B.V.
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Fruits and Seeds of Genera in the Subfamily Faboideae (Fabaceae)
Fruits and Seeds of United States Department of Genera in the Subfamily Agriculture Agricultural Faboideae (Fabaceae) Research Service Technical Bulletin Number 1890 Volume I December 2003 United States Department of Agriculture Fruits and Seeds of Agricultural Research Genera in the Subfamily Service Technical Bulletin Faboideae (Fabaceae) Number 1890 Volume I Joseph H. Kirkbride, Jr., Charles R. Gunn, and Anna L. Weitzman Fruits of A, Centrolobium paraense E.L.R. Tulasne. B, Laburnum anagyroides F.K. Medikus. C, Adesmia boronoides J.D. Hooker. D, Hippocrepis comosa, C. Linnaeus. E, Campylotropis macrocarpa (A.A. von Bunge) A. Rehder. F, Mucuna urens (C. Linnaeus) F.K. Medikus. G, Phaseolus polystachios (C. Linnaeus) N.L. Britton, E.E. Stern, & F. Poggenburg. H, Medicago orbicularis (C. Linnaeus) B. Bartalini. I, Riedeliella graciliflora H.A.T. Harms. J, Medicago arabica (C. Linnaeus) W. Hudson. Kirkbride is a research botanist, U.S. Department of Agriculture, Agricultural Research Service, Systematic Botany and Mycology Laboratory, BARC West Room 304, Building 011A, Beltsville, MD, 20705-2350 (email = [email protected]). Gunn is a botanist (retired) from Brevard, NC (email = [email protected]). Weitzman is a botanist with the Smithsonian Institution, Department of Botany, Washington, DC. Abstract Kirkbride, Joseph H., Jr., Charles R. Gunn, and Anna L radicle junction, Crotalarieae, cuticle, Cytiseae, Weitzman. 2003. Fruits and seeds of genera in the subfamily Dalbergieae, Daleeae, dehiscence, DELTA, Desmodieae, Faboideae (Fabaceae). U. S. Department of Agriculture, Dipteryxeae, distribution, embryo, embryonic axis, en- Technical Bulletin No. 1890, 1,212 pp. docarp, endosperm, epicarp, epicotyl, Euchresteae, Fabeae, fracture line, follicle, funiculus, Galegeae, Genisteae, Technical identification of fruits and seeds of the economi- gynophore, halo, Hedysareae, hilar groove, hilar groove cally important legume plant family (Fabaceae or lips, hilum, Hypocalypteae, hypocotyl, indehiscent, Leguminosae) is often required of U.S.
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Flowers of Asteraceae
Flowers of Asteraceae The 'flower' that you see is actually a head composed of many small florets. The head (capitulum) is an inflorescence and a number of capitula are often aggregated together to form a secondary inflorescence or synflorescence. The capitulum is surrounded on the outside by one or several layers of involucral bracts resembling the calyx of other flowers. These bracts are mostly green (herbaceous) but can also be brightly coloured like in everlastings (Helichrysum spp.) or can have a thin, dry, membranous texture (scarious). The involucral bracts are mostly free and arranged in one to many rows, overlapping like the tiles of a roof (imbricate). When in one row, they are often fused to different degrees. The florets in a head consist of one, two or rarely three out of six different kinds of florets. (1) The most obvious florets are the outer row of ray florets, resembling the petals of other flowering plants. The ray florets consist of laterally fused, elongated petals with three or four small upper lobes or teeth and are usually brightly coloured: yellow, blue, purple, pink, red or white and sometimes a combination of these colours. The ray florets are either female, which means they have a pistil, or they are neutral meaning that no sex organs are present or, if present, they are sterile. (2) A slight variation of these are the bilabiate ray florets. In these ray florets the outer, laterally fused petals are also elongated, but have three small upper lobes or teeth and smaller, laterally fused inner elongated petals with two upper lobes or teeth, almost like the flowers of the sage family (Lamiaceae).
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PHASEOLUS LESSON ONE PHASEOLUS and the FABACEAE INTRODUCTION to the FABACEAE
1 PHASEOLUS LESSON ONE PHASEOLUS and the FABACEAE In this lesson we will begin our study of the GENUS Phaseolus, a member of the Fabaceae family. The Fabaceae are also known as the Legume Family. We will learn about this family, the Fabaceae and some of the other LEGUMES. When we study about the GENUS and family a plant belongs to, we are studying its TAXONOMY. For this lesson to be complete you must: ___________ do everything in bold print; ___________ answer the questions at the end of the lesson; ___________ complete the world map at the end of the lesson; ___________ complete the table at the end of the lesson; ___________ learn to identify the different members of the Fabaceae (use the study materials at www.geauga4h.org); and ___________ complete one of the projects at the end of the lesson. Parts of the lesson are in underlined and/or in a different print. Younger members can ignore these parts. WORDS PRINTED IN ALL CAPITAL LETTERS may be new vocabulary words. For help, see the glossary at the end of the lesson. INTRODUCTION TO THE FABACEAE The genus Phaseolus is part of the Fabaceae, or the Pea or Legume Family. This family is also known as the Leguminosae. TAXONOMISTS have different opinions on naming the family and how to treat the family. Members of the Fabaceae are HERBS, SHRUBS and TREES. Most of the members have alternate compound leaves. The FRUIT is usually a LEGUME, also called a pod. Members of the Fabaceae are often called LEGUMES. Legume crops like chickpeas, dry beans, dry peas, faba beans, lentils and lupine commonly have root nodules inhabited by beneficial bacteria called rhizobia.
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The Usefulness of Edible and Medicinal Fabaceae in Argentine and Chilean Patagonia: Environmental Availability and Other Sources of Supply
Hindawi Publishing Corporation Evidence-Based Complementary and Alternative Medicine Volume 2012, Article ID 901918, 12 pages doi:10.1155/2012/901918 Research Article The Usefulness of Edible and Medicinal Fabaceae in Argentine and Chilean Patagonia: Environmental Availability and Other Sources of Supply Soledad Molares and Ana Ladio INIBIOMA, Universidad Nacional del Comahue-CONICET, Quintral 1250, Bariloche, R´ıo Negro 8400, Argentina Correspondence should be addressed to Ana Ladio, [email protected] Received 12 July 2011; Accepted 12 September 2011 Academic Editor: Maria Franco Trindade Medeiros Copyright © 2012 S. Molares and A. Ladio. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Fabaceae is of great ethnobotanical importance in indigenous and urban communities throughout the world. This work presents a revision of the use of Fabaceae as a food and/or medicinal resource in Argentine-Chilean Patagonia. It is based on a bibliographical analysis of 27 ethnobotanical sources and catalogues of regional ﬂora. Approximately 234 wild species grow in Patagonia, mainly (60%) in arid environments, whilst the remainder belong to Sub-Antarctic forest. It was found that 12.8% (30 species), mainly woody, conspicuous plants, are collected for food or medicines. Most of the species used grow in arid environments. Cultivation and purchase/barter enrich the Fabaceae oﬀer, bringing it up to a total of 63 species. The richness of native and exotic species, and the existence of multiple strategies for obtaining these plants, indicates hybridization of knowledge and practices.
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