Appendix A. Database Search Results
Total Page:16
File Type:pdf, Size:1020Kb
Load more
Recommended publications
-
Redalyc.Géneros De Lamiaceae De México, Diversidad Y Endemismo
Revista Mexicana de Biodiversidad ISSN: 1870-3453 [email protected] Universidad Nacional Autónoma de México México Martínez-Gordillo, Martha; Fragoso-Martínez, Itzi; García-Peña, María del Rosario; Montiel, Oscar Géneros de Lamiaceae de México, diversidad y endemismo Revista Mexicana de Biodiversidad, vol. 84, núm. 1, marzo, 2013, pp. 30-86 Universidad Nacional Autónoma de México Distrito Federal, México Disponible en: http://www.redalyc.org/articulo.oa?id=42526150034 Cómo citar el artículo Número completo Sistema de Información Científica Más información del artículo Red de Revistas Científicas de América Latina, el Caribe, España y Portugal Página de la revista en redalyc.org Proyecto académico sin fines de lucro, desarrollado bajo la iniciativa de acceso abierto Revista Mexicana de Biodiversidad 84: 30-86, 2013 DOI: 10.7550/rmb.30158 Géneros de Lamiaceae de México, diversidad y endemismo Genera of Lamiaceae from Mexico, diversity and endemism Martha Martínez-Gordillo1, Itzi Fragoso-Martínez1, María del Rosario García-Peña2 y Oscar Montiel1 1Herbario de la Facultad de Ciencias, Facultad de Ciencias, Universidad Nacional Autónoma de México. partado postal 70-399, 04510 México, D.F., México. 2Herbario Nacional de México, Instituto de Biología, Universidad Nacional Autónoma de México. Apartado postal 70-367, 04510 México, D.F., México. [email protected] Resumen. La familia Lamiaceae es muy diversa en México y se distribuye con preferencia en las zonas templadas, aunque es posible encontrar géneros como Hyptis y Asterohyptis, que habitan en zonas secas y calientes; es una de las familias más diversas en el país, de la cual no se tenían datos actualizados sobre su diversidad y endemismo. -
The Genetic Structure of Species' Geographic
THE GENETIC STRUCTURE OF SPECIES’ GEOGRAPHIC RANGES: AN EVALUATION USING THE COSTAL DUNE ENDEMIC CAMISSONIOPSIS CHEIRANTHIFOLIA (ONAGRACEAE) By Adriana López Villalobos A thesis submitted to the Department of Biology in conformity with the requirements for the Degree of Doctor of Philosophy Queen’s University Kingston, Ontario Canada June 2017 Copyright © Adriana López-Villalobos, 2017 ABSTRACT The development of molecular techniques has spurred thousands of population genetic studies on a wide variety of plant and animal species. Particularly important, but still relatively rare, are studies that properly test for geographic variation in genetic structure across species’ ranges. This thesis investigates the effects of population density, mating system variation, distance between populations and hybridization on the genetic diversity, differentiation and structure across the range of Camissoniopsis cheiranthifolia (Onagraceae). By combining a transplant experiment with microsatellites, I also provide an empirical test of one of the most poorly resolved questions in evolutionary biology: Why do species exhibit limits to their distributions? I developed 24 species-specific nuclear microsatellites loci (nSSR) and used 13 of these and six variable chloroplast microsatellites (cpSSR) to investigate the genetic consequences of the transition from outcrossing to selfing in C. cheiranthifolia. As predicted, small-flowered, selfing populations had lower nSSR diversity (but not cpSSR) than large-flowered, outcrossing populations but they were not more differentiated. The reduction in diversity was greater than the expected from selfing alone, but could not be accounted for by indirect effects of selfing on population density. Five parapatric nSSR clusters and three groups of cpSSR haplotypes usually (but not always) differed in mating system, suggesting that selfing may often initiate ecogeographic isolation. -
Non-Local Natives and Non-Native Locals: Considerations in the Management of Rare Or Endangered Species
Non-Local Natives and Non-Native Locals: Considerations in the Management of Rare or Endangered Species Deborah L. Rogers Center for Natural Lands Management and AES/Plant Sciences, UC Davis A nd: Peter W. Dunwiddie (CNLM) Jennifer DeWoody (NFGEL, USDA FS) Valerie Hipkins (NFGEL, USDA FS) Structure 1. Risks of moving species (creating or maintaining non-native) 2. Risks of protecting species integrity 3. Risks of moving populations • Four case studies • Western US (WA, OR, CA) • Rare, endangered plant species 1. Risks of moving species (creating or maintaining non-natives) Case study #1: Taylor’s checkerspot and Lanceleaf (English) plantain Butterfly status: ESA Endangered October 2013 Taylor’s checkerspot Photo: Rod Gilbert (Euphydryas editha taylori) Taylor’s checkerspot: Extant locations rangewide • 74 known historical sites • Many were lowland prairies • 13 extant sites • 4 sites lost in South Puget Trough in 1998-2000 • Historically occurred in large numbers (>10,000) • Estimates of abundance: >500 adults at 5 sites, >100 adults at 2 sites; <100 at 4 Source: Mary Linders, WDFW Prairie and butterfly habitat restoration • Control invasive species • Restore ecological processes (fire) • Enhance species diversity • Especially larval host plants and nectar sources Checkerspot larval host plants Plantago lanceolata Plectritis congesta (non-native) Castilleja hispida Collinsia grandiflora & C. parviflora Castilleja levisecta Photos: Rod Gilbert Management Challenges: Phenological fit Mid May Late May Mid June Late June Lanceleaf plantain -
Evolution of Angiosperm Pollen. 7. Nitrogen-Fixing Clade1
Evolution of Angiosperm Pollen. 7. Nitrogen-Fixing Clade1 Authors: Jiang, Wei, He, Hua-Jie, Lu, Lu, Burgess, Kevin S., Wang, Hong, et. al. Source: Annals of the Missouri Botanical Garden, 104(2) : 171-229 Published By: Missouri Botanical Garden Press URL: https://doi.org/10.3417/2019337 BioOne Complete (complete.BioOne.org) is a full-text database of 200 subscribed and open-access titles in the biological, ecological, and environmental sciences published by nonprofit societies, associations, museums, institutions, and presses. Your use of this PDF, the BioOne Complete website, and all posted and associated content indicates your acceptance of BioOne’s Terms of Use, available at www.bioone.org/terms-of-use. Usage of BioOne Complete content is strictly limited to personal, educational, and non - commercial use. Commercial inquiries or rights and permissions requests should be directed to the individual publisher as copyright holder. BioOne sees sustainable scholarly publishing as an inherently collaborative enterprise connecting authors, nonprofit publishers, academic institutions, research libraries, and research funders in the common goal of maximizing access to critical research. Downloaded From: https://bioone.org/journals/Annals-of-the-Missouri-Botanical-Garden on 01 Apr 2020 Terms of Use: https://bioone.org/terms-of-use Access provided by Kunming Institute of Botany, CAS Volume 104 Annals Number 2 of the R 2019 Missouri Botanical Garden EVOLUTION OF ANGIOSPERM Wei Jiang,2,3,7 Hua-Jie He,4,7 Lu Lu,2,5 POLLEN. 7. NITROGEN-FIXING Kevin S. Burgess,6 Hong Wang,2* and 2,4 CLADE1 De-Zhu Li * ABSTRACT Nitrogen-fixing symbiosis in root nodules is known in only 10 families, which are distributed among a clade of four orders and delimited as the nitrogen-fixing clade. -
Palynological Evolutionary Trends Within the Tribe Mentheae with Special Emphasis on Subtribe Menthinae (Nepetoideae: Lamiaceae)
Plant Syst Evol (2008) 275:93–108 DOI 10.1007/s00606-008-0042-y ORIGINAL ARTICLE Palynological evolutionary trends within the tribe Mentheae with special emphasis on subtribe Menthinae (Nepetoideae: Lamiaceae) Hye-Kyoung Moon Æ Stefan Vinckier Æ Erik Smets Æ Suzy Huysmans Received: 13 December 2007 / Accepted: 28 March 2008 / Published online: 10 September 2008 Ó Springer-Verlag 2008 Abstract The pollen morphology of subtribe Menthinae Keywords Bireticulum Á Mentheae Á Menthinae Á sensu Harley et al. [In: The families and genera of vascular Nepetoideae Á Palynology Á Phylogeny Á plants VII. Flowering plantsÁdicotyledons: Lamiales (except Exine ornamentation Acanthaceae including Avicenniaceae). Springer, Berlin, pp 167–275, 2004] and two genera of uncertain subtribal affinities (Heterolamium and Melissa) are documented in Introduction order to complete our palynological overview of the tribe Mentheae. Menthinae pollen is small to medium in size The pollen morphology of Lamiaceae has proven to be (13–43 lm), oblate to prolate in shape and mostly hexacol- systematically valuable since Erdtman (1945) used the pate (sometimes pentacolpate). Perforate, microreticulate or number of nuclei and the aperture number to divide the bireticulate exine ornamentation types were observed. The family into two subfamilies (i.e. Lamioideae: bi-nucleate exine ornamentation of Menthinae is systematically highly and tricolpate pollen, Nepetoideae: tri-nucleate and hexa- informative particularly at generic level. The exine stratifi- colpate pollen). While the -
Baccharis Malibuensis (Asteraceae): a New Species from the Santa Monica Mountains, California R
Aliso: A Journal of Systematic and Evolutionary Botany Volume 14 | Issue 3 Article 32 1995 Baccharis Malibuensis (Asteraceae): A New Species from the Santa Monica Mountains, California R. Mitchell Beauchamp Pacific Southwest Biological Services, Inc. James Henrickson California State University, Los Angeles Follow this and additional works at: http://scholarship.claremont.edu/aliso Part of the Botany Commons Recommended Citation Beauchamp, R. Mitchell and Henrickson, James (1995) "Baccharis Malibuensis (Asteraceae): A New Species from the Santa Monica Mountains, California," Aliso: A Journal of Systematic and Evolutionary Botany: Vol. 14: Iss. 3, Article 32. Available at: http://scholarship.claremont.edu/aliso/vol14/iss3/32 Aliso, 14(3), pp. 197-203 © 1996, by The Rancho Santa Ana Botanic Garden, Claremont, CA 91711-3157 BACCHARIS MALIBUENSIS (ASTERACEAE): A NEW SPECIES FROM THE SANTA MONICA MOUNTAINS, CALIFORNIA R. MITCHEL BEAUCHAMP Pacific Southwest Biological Services, Inc. P.O. Box 985 National City, California 91951 AND JAMES HENRICKSON Department of Biology California State University Los Angeles, California 90032 ABSTRACT Baccharis malibuensis is described from the Malibu Lake region of the Santa Monica Mountains, Los Angeles County, California. It is closely related to Baccharis plummerae subsp. plummerae but differs in having narrow, subentire, typically conduplicate, sparsely villous to mostly glabrous leaves with glands occurring in depressions on the adaxial surface, more cylindrical inflorescences, and a distribution in open chaparral vegetation. The new taxon shares some characteristics with B. plum merae subsp. glabrata of northwestern San Luis Obispo County, e.g., smaller leaves, reduced vestiture, and occurrence in scrub habitat, but the two taxa appear to have developed independently from B. -
Section 5 References
Section 5 References 5.0 REFERENCES Akçakaya, H. R. and J. L. Atwood. 1997. A habitat-based metapopulation model of the California Gnatcatcher. Conservation Biology 11:422-434. Akçakaya, H.R. 1998. RAMAS GIS: Linking landscape data with population viability analysis (version 3.0). Applied Biomathematics, Setaauket, New York. Anderson, D.W. and J.W. Hickey. 1970. Eggshell changes in certain North American birds. Ed. K. H. Voous. Proc. (XVth) Inter. Ornith. Congress, pp 514-540. E.J. Brill, Leiden, Netherlands. Anderson, D.W., J.R. Jehl, Jr., R.W. Risebrough, L.A. Woods, Jr., L.R. Deweese, and W.G. Edgecomb. 1975. Brown pelicans: improved reproduction of the southern California coast. Science 190:806-808. Atwood, J.L. 1980. The United States distribution of the California black-tailed gnatcatcher. Western Birds 11: 65-78. Atwood, J.L. 1990. Status review of the California gnatcatcher (Polioptila californica). Unpublished Technical Report, Manomet Bird Observatory, Manomet, Massachusetts. Atwood, J.L. 1992. A maximum estimate of the California gnatcatcher’s population size in the United States. Western Birds. 23:1-9. Atwood, J.L. and J.S. Bolsinger. 1992. Elevational distribution of California gnatcatchers in the United States. Journal of Field Ornithology 63:159-168. Atwood, J.L., S.H. Tsai, C.H. Reynolds, M.R. Fugagli. 1998. Factors affecting estimates of California gnatcatcher territory size. Western Birds 29: 269-279. Baharav, D. 1975. Movement of the horned lizard Phrynosoma solare. Copeia 1975: 649-657. Barry, W.J. 1988. Management of sensitive plants in California state parks. Fremontia 16(2):16-20. Beauchamp, R.M. -
Coastal Cactus Wren & California Gnatcatcher Habitat Restoration Project
Coastal Cactus Wren & California Gnatcatcher Habitat Restoration Project Encanto and Radio Canyons San Diego, CA Final Report AECOM and GROUNDWORK SAN DIEGO-CHOLLAS CREEK for SANDAG April 2011 TABLE OF CONTENTS BACKGROUND ............................................................................................................................................... 1 PRE-IMPLEMENTATION ................................................................................................................................. 2 Project Boundary Definition ................................................................................................................ 2 Vegetation Mapping and Species Inventory ....................................................................................... 2 Coastal Cactus Wren and California Gnatcatcher Surveys .................................................................. 8 Cholla Harvesting .............................................................................................................................. 11 Plant Nursery Site Selection and Preparation ................................................................................... 12 Cholla Propagation ............................................................................................................................ 12 ON-SITE IMPLEMENTATION ........................................................................................................................ 12 Site Preparation................................................................................................................................ -
Southern Gulf, Queensland
Biodiversity Summary for NRM Regions Species List What is the summary for and where does it come from? This list has been produced by the Department of Sustainability, Environment, Water, Population and Communities (SEWPC) for the Natural Resource Management Spatial Information System. The list was produced using the AustralianAustralian Natural Natural Heritage Heritage Assessment Assessment Tool Tool (ANHAT), which analyses data from a range of plant and animal surveys and collections from across Australia to automatically generate a report for each NRM region. Data sources (Appendix 2) include national and state herbaria, museums, state governments, CSIRO, Birds Australia and a range of surveys conducted by or for DEWHA. For each family of plant and animal covered by ANHAT (Appendix 1), this document gives the number of species in the country and how many of them are found in the region. It also identifies species listed as Vulnerable, Critically Endangered, Endangered or Conservation Dependent under the EPBC Act. A biodiversity summary for this region is also available. For more information please see: www.environment.gov.au/heritage/anhat/index.html Limitations • ANHAT currently contains information on the distribution of over 30,000 Australian taxa. This includes all mammals, birds, reptiles, frogs and fish, 137 families of vascular plants (over 15,000 species) and a range of invertebrate groups. Groups notnot yet yet covered covered in inANHAT ANHAT are notnot included included in in the the list. list. • The data used come from authoritative sources, but they are not perfect. All species names have been confirmed as valid species names, but it is not possible to confirm all species locations. -
BIODIVERSITY CONSERVATION on the TIWI ISLANDS, NORTHERN TERRITORY: Part 1. Environments and Plants
BIODIVERSITY CONSERVATION ON THE TIWI ISLANDS, NORTHERN TERRITORY: Part 1. Environments and plants Report prepared by John Woinarski, Kym Brennan, Ian Cowie, Raelee Kerrigan and Craig Hempel. Darwin, August 2003 Cover photo: Tall forests dominated by Darwin stringybark Eucalyptus tetrodonta, Darwin woollybutt E. miniata and Melville Island Bloodwood Corymbia nesophila are the principal landscape element across the Tiwi islands (photo: Craig Hempel). i SUMMARY The Tiwi Islands comprise two of Australia’s largest offshore islands - Bathurst (with an area of 1693 km 2) and Melville (5788 km 2) Islands. These are Aboriginal lands lying about 20 km to the north of Darwin, Northern Territory. The islands are of generally low relief with relatively simple geological patterning. They have the highest rainfall in the Northern Territory (to about 2000 mm annual average rainfall in the far north-west of Melville and north of Bathurst). The human population of about 2000 people lives mainly in the three towns of Nguiu, Milakapati and Pirlangimpi. Tall forests dominated by Eucalyptus miniata, E. tetrodonta, and Corymbia nesophila cover about 75% of the island area. These include the best developed eucalypt forests in the Northern Territory. The Tiwi Islands also include nearly 1300 rainforest patches, with floristic composition in many of these patches distinct from that of the Northern Territory mainland. Although the total extent of rainforest on the Tiwi Islands is small (around 160 km 2 ), at an NT level this makes up an unusually high proportion of the landscape and comprises between 6 and 15% of the total NT rainforest extent. The Tiwi Islands also include nearly 200 km 2 of “treeless plains”, a vegetation type largely restricted to these islands. -
SAN DIEGO COUNTY NATIVE PLANTS in the 1830S
SAN DIEGO COUNTY NATIVE PLANTS IN THE 1830s The Collections of Thomas Coulter, Thomas Nuttall, and H.M.S. Sulphur with George Barclay and Richard Hinds James Lightner San Diego Flora San Diego, California 2013 SAN DIEGO COUNTY NATIVE PLANTS IN THE 1830s Preface The Collections of Thomas Coulter, Thomas Nuttall, and Our knowledge of the natural environment of the San Diego region H.M.S. Sulphur with George Barclay and Richard Hinds in the first half of the 19th century is understandably vague. Referenc- es in historical sources are limited and anecdotal. As prosperity peaked Copyright © 2013 James Lightner around 1830, probably no more than 200 inhabitants in the region could read and write. At most one or two were trained in natural sciences or All rights reserved medicine. The best insights we have into the landscape come from nar- No part of this document may be reproduced or transmitted in any form ratives of travelers and the periodic reports of the missions’ lands. They without permission in writing from the publisher. provide some idea of the extent of agriculture and the general vegeta- tion covering surrounding land. ISBN: 978-0-9749981-4-5 The stories of the visits of United Kingdom naturalists who came in Library of Congress Control Number: 2013907489 the 1830s illuminate the subject. They were educated men who came to the territory intentionally to examine the flora. They took notes and col- Cover photograph: lected specimens as botanists do today. Reviewing their contributions Matilija Poppy (Romneya trichocalyx), Barrett Lake, San Diego County now, we can imagine what they saw as they discovered plants we know. -
Appendix B Biological Resources Analysis
Appendix B Biological Resources Analysis INTENTIONALLY LEFT BLANK 38 NORTH MARENGO AVENUE PASADENA. CALIFORNIA 91101 T 626.204.9800 F 626.204.9834 MEMORANDUM From: Michael Cady – Senior Biologist Subject: Biological Resources Analysis for the Buena Vista Project Date: August 18, 2020 Attachment(s): A) Photo Exhibit; B) Google Earth Imagery of the Project Site; C) Plant Compendium; D) Wildlife Compendium; E) Sensitive Resources Databases Query Results; F) Historic California Natural Diversity Database Records; G) Special-Status Plant Species Potential to Occur; H) Special-Status Wildlife Species Potential to Occur; I) Historical Aerial Imagery of the Project Site from 1948; J) National Wetlands Inventory Results; K) Wildlife Corridors and Habitat Connectivity Exhibit; L) California Natural Community Conservation Plans This memorandum (memo) details the methodology and results of Dudek’s site visit and analysis for the potential occurrence of sensitive resources within the proposed Buena Vista Project (project). The Project site is located at 1030–1380 North Broadway and 1251 North Spring Street, within the vicinity of the Chinatown neighborhood, downtown Los Angeles, Lincoln Heights, and Dodger Stadium/Elysian Park. The analysis was conducted in support of the Initial Study (IS) for the project to determine if additional studies or analysis are necessary. Methodology A review of existing information and a site visit was conducted to determine the biological resources that are present or have potential to occur on and adjacent to the project site. Literature Review A literature review was conducted prior to the field visit to identify special-status biological resources present or potentially present within the vicinity of the project site using the following: • California Department of Fish and Wildlife (CDFW) California Natural Diversity Database (CNDDB) (CDFW 2020a) • California Native Plant Society’s (CNPS) Online Inventory of Rare and Endangered Vascular Plants (CNPS 2020) • U.S.