DOCSLIB.ORG

Appendix 6 Plots of Absolute Diversification Age Estimates (Ma

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Appendix 6 Plots of Absolute Diversification Age Estimates (Ma Morvan et al. Timetree of Aselloidea reveals species diversification dynamics in groundwater Appendix 6 Appendix 6 Plots of absolute diversification age estimates (Ma) for different Bayesian relaxed molecular clock models. Left and right panels correspond to data sets inferred by the GMYC method and thresh- old method, respectively. Age estimates along the X-axis are from the uncorrelated lognormal model (BEAST), whereas dating estimates along the Y-axis in the upper and lower panels are from the uncor- related exponential model (BEAST) and the correlated lognormal model (Multidivtime), respectively. Solid lines show linear regressions between age estimations for the different models, and dotted lines in- dicate 1:1 equivalence relationships. Error bars represent 95% posterior density (HPD) intervals for each node. Dating estimates were plotted for 20 benchmark clades spanning Aselloidea diversity: Aselloidea crown group diversification, Asellidae crown group diversification, Stenasellidae crown group diversifica- tion, Bragasellus/Synasellus/Lirceolus/Gallasellus/Caecidotea/Remasellus crown group diversification, Proasellus crown group diversification, divergence between Mexistenasellus coahuila and Stenasellus gal- hanoe, divergence between Proasellus coxalis lineage and Proasellus Alpine/Ibero-aquitanian lineages, divergence between Proasellus Alpine lineage and Proasellus Ibero-aquitanian lineage, divergence be- tween Stenasellus virei/Stenasellus buili clade and other Stenasellus species, Proasellus coxalis lineage crown group diversification, Lirceolus/Gallasellus/Caecidotea/Remasellus crown group diversification, Proasellus Alpine lineage crown group diversification, Spanish Bragasellus crown group diversification, Proasellus Ibero-aquitanian lineage crown group diversification, Proasellus slavus lineage crown group diversification, Asellus crown group diversification, divergence between Proasellus coiffaiti and Proasel- lus slovenicus, Synasellus crown group diversification, and divergence between Proasellus beroni and Proasellus ligusticus. 1.
Load more

Recommended publications
  • Natur Und Heimat
    Natur u. Heimat, 37. Jahrg., Heft 3, 1977 (1968): Gehäuse von Insekten-Larven, insbesondere von Chironomiden, in quar­ tären Sedimenten. Mitt. Geol. Inst. Univers. Hannover, 8, 34-53. ___.:._ HrLTERMANN, H. (1975): Kleiner Führer durch Solbad Laer T. W. Suderberger Hefte 1. - HrL­ TERMANN, H . (1976): Ein vergessener mittelalterlicher Baustein. Jb. Heimatbund Osnabrück-Land, 54-59. - HrLTERMANN, H. & K. MÄDLER (1977): Charophyten als palökologische Indikatoren und ihr Vorkommen in den Sinterkalken von Bad Laer T. W. Paläontol. Z. (im Druck). - ZEISSLER, H. (1977): Konchylien aus dem holozänen Travertin von Bad Laer, Kreis Osnabrück. (im Druck). Anschrift des Verfassers1: Prof. Dr. H. Hiltermann, Milanring 11, D-4518 Bad Laer. Die ersten Nachweise der Wasserassel Proasellus meridianus CRacovitza, 1919) (Crustacea, Isopoda Asellidae) im Einzugsgebiet der Ems KARL FRIEDRICH HERHAUS, Münster In Deutschland ist die von HENRY und MAGNIEZ (1970) revidierte Familie Asellida,e Sars, 1899, mit drei oberirdischen Arten vertreten. Die am weitesten verbreitete Art ist Asellus ( Asellus) aquaticus (L., 175 8); sie ist ein sibirisches Faunenelement, das sich postglazial nach Westen hin ausgebreitet hat (BrRSTEIN 1951; WILLIAMS 1962). Weitaus weniger häufig tritt die zweite Art, Proasellus coxalis (Dollfus, 1892), auf; diese im übrigen circummediterran verbreitete Art ist in Mittel­ europa mit der Unterart septentrionalis (Herbst, 1956) vertreten, die vermutlich erst in jüngster Zeit eingeschleppt worden ist (HERHAUS 1977). Am seltensten ist auf deutschem Boden die dritte Art, Proasellus meridianus (Racovitza, 1919). P. meridianus ist eine autochthon west­ europä,isch-atlantische Form (GRUNER 1965); in Deutschland wurde sie von STAMMER (1932) am linken Niederrhein nachgewiesen. Für die sichere Bestimmung der drei Arten ist die Untersuchung der Pleopoden II unter dem Binokular unerläßlich.
    [Show full text]
  • Isopoda, Asellota) with Some Phylogenetic Considerations Concerning Asellota
    Crustaceana 48 (2) 1985, E. J. Brill, Leiden A CONTRIBUTION TO THE GENERAL MORPHOLOGY OF PROTOJANIRIDAE (ISOPODA, ASELLOTA) WITH SOME PHYLOGENETIC CONSIDERATIONS CONCERNING ASELLOTA BY B. SKET Institut za biologijo, Univerza E. Kardelja v Ljubljani, p.p. 141, YU 61001 Ljubljana, Yugoslavia Since most representatives of the superfamily Gnathostenetroidoidea have been described only for "microtaxonomical" purposes, some important features and even peculiarities of the species and probably of the entire group have been overlooked. I took advantage of possessing a good sample of the comparatively very large representative, viz., Enckella lucei major Sket, 1982 (as well as some other species of the family Protojaniridae) to demonstrate some such features. Unfortunately, of the family Gnathostenetroididae I could study only specimens of an undescribed species from the Bahamas, while comparison with other representatives was possible only through illustrations. I abstained from comparing Enckella with the numerous and diverse Janiroidea, leaving this to a more versed student of that special group. I also abstained from discussing the remarkable idea about possible Asellotan nature of Microcerberidae (WageJe, J 980) which is anyway of little importance for the present subject. Cephalothorax ("head"). — With the exception of having two pairs of antennae, the Enckella's head bears greater resemblance to a prognathous in­ sect head than to an Asellid. The cephalic capsula is closed to a great extent, incorporating completely the first thoracomere. The capsula is closed and slightly sclerotised also behind the insertions of the maxillipeds, uniting them with the set of other mouth appendages. The clypeolabrum protrudes for­ wards, its inclination downwards is much less expressed than in most other groups of Isopoda.
    [Show full text]
  • •Not! Ptdition, X:213-230
    78 SMITHSONIAN CONTRIBUTIONS TO ZOOLOGY Carman, S. Knjyer, H. 1889. Cave Animal j from South we item Missouri. Bulle­ 1838. Gronlands Amphipoder. Kongelige danske viden* tin of the Museum of Comparative Zoology, skabernes Selskabbiologiske Skrifter, 7:229-326. 17(6):225-239. Latreille, P. A. Geoffrey Saint-Hilaire, E. L. 1803. Histoire naturelle, ginirale et particuliire, des 1764. Histoire abrigie dts Insectes qui se troitvcnt aux Cruslacis et dts Insectes, 6:1-391. Paris.* environs de Paris. Pari*.* Leonard, A. B,, and L. H. Ponder Gould, A. A, 1949. Crustacea of Eastern Kansas. Transactions of the 1841. Report on the Invertebrate Animals of Massachu­ Kansas Academy of Science, 52:168-204. setts. Cambridge: Massachusetts. Levi, H. W. Gruner, H. £. 1949. Two New Species of Cave Isopods from Pennsyl­ 1965. Die Tierwelt Deutschlands. Krebstiere oder Crus­ vania. Notulae Naturae, 220:1-fi. tacea. V, Isopoda. 53. Teil, 2 Lf. Jena. Linnaeus, C. Hansen, H. J. 1758. Systema Naturae. 10th Edition, 824 pages* 1888. Oversigt over det vestlige Gronlands Fauna. Mac Lin, J. G. Videnskabelige Meddeletier jra dansk Naturhis- 1940. A Key to the Oklahoma Species of the Family torisk Forening Kjobenhacn, 1887:177-198. Asellidae. Proceedings of the Oklahoma Academy Harford, W. G. W. of Science, 20:17-18. 1877. Description of a New Genus and Three New Spe­ Mackin, J. G, and L. Hubricht cies of Sessile Eyed Crustacea. Proceedings of the 1938. Records of Distribution of Species of Isopods in California Academy of Science, 7:53-55. Central and Southern United States, with Descrip­ Harger, O. tions of Four New Species of Mancasellus and 1874.
    [Show full text]
  • Identification of Freshwater Invertebrates
    Identification of Freshwater Invertebrates © 2008 Pennsylvania Sea Grant To request copies, please contact: Sara Grisé email: [email protected] Table of Contents A. Benthic Macroinvertebrates……………………….………………...........…………1 Arachnida………………………………..………………….............….…2 Bivalvia……………………...…………………….………….........…..…3 Clitellata……………………..………………….………………........…...5 Gastropoda………………………………………………………..............6 Hydrozoa………………………………………………….…………....…8 Insecta……………………..…………………….…………......…..……..9 Malacostraca………………………………………………....…….…....22 Turbellaria…………………………………………….….…..........…… 24 B. Plankton…………………………………………...……….………………............25 Phytoplankton Bacillariophyta……………………..……………………...……….........26 Chlorophyta………………………………………….....…………..........28 Cyanobacteria…...……………………………………………..…….…..32 Gamophyta…………………………………….…………...….…..…….35 Pyrrophycophyta………………………………………………………...36 Zooplankton Arthropoda……………………………………………………………....37 Ciliophora……………………………………………………………......41 Rotifera………………………………………………………………......43 References………………………………………………………….……………….....46 Taxonomy is the science of classifying and naming organisms according to their characteris- tics. All living organisms are classified into seven levels: Kingdom, Phylum, Class, Order, Family, Genus, and Species. This book classifies Benthic Macroinvertebrates by using their Class, Family, Genus, and Species. The Classes are the categories at the top of the page in colored text corresponding to the color of the page. The Family is listed below the common name, and the Genus and Spe- cies names
    [Show full text]
  • Native and Exotic Amphipoda and Other Peracarida in the River Meuse: New Assemblages Emerge from a Fast Changing Fauna
    Hydrobiologia (2005) 542:203–220 Ó Springer 2005 H. Segers & K. Martens (eds), Aquatic Biodiversity II DOI 10.1007/s10750-004-8930-9 Native and exotic Amphipoda and other Peracarida in the River Meuse: new assemblages emerge from a fast changing fauna Guy Josens1,*, Abraham Bij de Vaate2, Philippe Usseglio-Polatera3, Roger Cammaerts1,4, Fre´de´ric Che´rot1,4, Fre´de´ric Grisez1,4, Pierre Verboonen1 & Jean-Pierre Vanden Bossche1,4 1Universite´ Libre de Bruxelles, Service de syste´matique et d’e´cologie animales, av. Roosevelt, 50, cp 160/13, B-1050 Bruxelles 2Institute for Inland Water Management & Waste Water Treatment, Lelystad, The Netherlands 3Universite´ de Metz, LBFE, e´quipe de De´moe´cologie, av. Ge´ne´ral Delestraint, F-57070 Metz 4Centre de Recherche de la Nature, des Foreˆts et du Bois, DGRNE, Ministe`re de la Re´gion wallonne, Avenue Mare´chal Juin, 23, B-5030 Gembloux (*Author for correspondence: e-mail: [email protected]) Key words: aquatic biodiversity, alien species, invasive species, invasibility, community dynamics, Dikerogammarus villosus, Chelicorophium curvispinum Abstract Samples issued from intensive sampling in the Netherlands (1992–2001) and from extensive sampling carried out in the context of international campaigns (1998, 2000 and 2001) were revisited. Additional samples from artificial substrates (1992–2003) and other techniques (various periods) were analysed. The combined data provide a global and dynamic view on the Peracarida community of the River Meuse, with the focus on the Amphipoda. Among the recent exotic species found, Crangonyx pseudogracilis is regressing, Dikerogammarus haemobaphes is restricted to the Condroz course of the river, Gammarus tigrinus is restricted to the lowlands and seems to regress, Jaera istri is restricted to the ‘tidal’ Meuse, Chelicorophium curvispinum is still migrating upstream into the Lorraine course without any strong impact on the other amphipod species.
    [Show full text]
  • II. Sampling Design
    National Park Service U.S. Department of the Interior Natural Resource Program Center Protocol for Monitoring Aquatic Invertebrates of Small Streams in the Heartland Inventory & Monitoring Network Natural Resource Report NPS/HTLN/NRR—2008/042 A Heartland Network Monitoring Protocol protecting the habitat of our heritage i ON THE COVER Herbert Hoover birthplace cottage at Herbert Hoover NHS, prescribed fire at Tallgrass Prairie NPres, aquatic invertebrate monitoring at George Washington Carver NM, the Mississippi River at Effigy Mounds NM. ii Protocol for Monitoring Aquatic Invertebrates of Small Streams in the Heartland Inventory & Monitoring Network David E. Bowles, Michael H. Williams, Hope R. Dodd, Lloyd W. Morrison, Janice A. Hinsey, Catherine E. Ciak, Gareth A. Rowell, Michael D. DeBacker, and Jennifer L. Haack National Park Service Heartland I&M Network Wilson’s Creek National Battlefield 6424 West Farm Road 182 Republic, Missouri 65738 June 2008 U.S. Department of the Interior National Park Service Natural Resource Program Center Fort Collins, Colorado i The Natural Resource Publication series addresses natural resource topics that are of interest and applicability to a broad readership in the National Park Service and to others in the management of natural resources, including the scientific community, the public, and the NPS conservation and environmental constituencies. Manuscripts are peer- reviewed to ensure that the information is scientifically credible, technically accurate, appropriately written for the intended audience, and is designed and published in a professional manner. Natural Resource Reports are the designated medium for disseminating high priority, current natural resource management information with managerial application. The series targets a general, diverse audience, and may contain NPS policy considerations or address sensitive issues of management applicability.
    [Show full text]
  • Crustacea: Isopoda: Asellidae)
    Int. J. Speleol. 7 (1975) pp. 339-356. Three New Trogldbitic Asellids from Western North America (Crustacea: Isopoda: Asellidae) by Thomas E. BOWMAN* "Vlajto -- ^. ^ Troglobitic isopods of the family Asellidae, comprising about 42 species (Fleming, 1973), are widespread in the eastern United States, mostly in non-glaciated areas, but extending into some glaciated parts of Illinois and Indiana. To the west, tro- globitic asellids range to central Kansas, Oklahoma and Texas. West of this area, if we exclude the 4 Mexican species of Mexistenasellus (Cole and Minckley, 1972; Magniez, 1972; Argano, 1973) which belong to a separate family, Stenasellidae (Henry and Magniez, 1968, 1970), only 2 troglobitic asellids are known from North America: Asellus californicus Miller (1933) from northern California and Conasellus pasquinii Argano (1972) from Veracruz state, Mexico. The 3 new species of western troglobitic asellids described herein extend the records of blind asellids in North America south to Chiapas state, Mexico, and north to central Alberta, Canada (ca. 53''N), and add a second species from Califor­ nia. The new species from Chiapas is very similar to Conasellus pasquinii Argano (1972); the new asellids from Alberta and California show no close affinities with known species. The generic status of North American species of Asellus is still unsettled. Henry and Magniez (1970) divided tlie species between Conasellus Stammer (1932) and ,- Pseudobaicalasellus Henry and Magniez (1968) except A. tomalensis Harford and ... A. californicus Miller, which they believed to be closely related to far-eastern forms belonging to Aseltus (Asellus) and Nipponasellus Matsumoto (1962). I have indi- " cated that this is unlikely for A.
    [Show full text]
  • Isopoda: Asellota: Aselloidea, Gnathostenetroidoidea, Stenetrioidea
    ISOPODA: ASELLOTA: ASELLOIDEA, GNATHOSTENETROIDOIDEA, STENETRIOIDEA J.-P. HENRY*, J. J. LEWIS** & G. MAGNIEZ* Les Asellota regroupent des lignées très différentes d'Isopo- Les Stenetriidae (fig. 11) et les Gnathostenetroididae (fig des, les unes vivant en milieu marin, les autres en eau douce. 10) sont deux petits groupes essentiellement marins, mais de Les unes et les autres ont souvent été étudiées par des zoolo­ récentes prospections ont amené la découverte d'un repré­ gistes différents, ce qui n'a pas toujours facilité l'établisse­ sentant de chacun dans les eaux souterraines (respective­ ment d'une systématique cohérente. Si l'on considère les ment dans l'interstitiel littoral de Curaçao et dans les eaux deux ensembles majeurs: les Janiroidea, essentiellement karstiques de l'île San Salvador, Bahamas). Ils fournissent marins et les Aselloidea, totalement dulçaquicoles, il semble un exemple d'apport direct de la faune marine à la faune que leurs thèmes évolutifs principaux soient radicalement stygobie. Les Protojaniridae, actuellement groupés avec les différents. Chez les Janiroïdes, la tendance à l'incorporation Gnathostenetroididae dans les Gnathostenetroidoidea pos­ progressive au pléotelson de tous les segments antérieurs du sèdent seulement le pléonite 1 libre (fig. 14). C'est un petit pléon prédomine; elle ne laisse finalement subsister aucun groupe caractéristique des eaux douces souterraines du pléonite libre chez les plus évolués. Mais cette évolution va domaine gondwanien: Afrique du Sud, Ceylan (Sket, 1982). de pair avec une conservation de l'ambivalence des pléopo- Les Aselloïdes forment l'ensemble de loin le plus riche en des 1 et 2 (coexistence des rôles operculaire et sexuel), qui les espèces stygobies et se répartissent en: a fixés dans un état peu différencié.
    [Show full text]
  • Phenotypic Plasticity As a Mechanism of Cave Colonization and Adaptation
    RESEARCH ARTICLE Phenotypic plasticity as a mechanism of cave colonization and adaptation Helena Bilandzˇija1,2, Breanna Hollifield1, Mireille Steck3, Guanliang Meng4,5, Mandy Ng1, Andrew D Koch6, Romana Gracˇan7, Helena C´ etkovic´ 2, Megan L Porter3, Kenneth J Renner6, William Jeffery1* 1Department of Biology, University of Maryland, College Park, United States; 2Department of Molecular Biology, Ruđer Bosˇkovic´ Institute, Zagreb, Croatia; 3Department of Biology, University of Hawai’i at Manoa, Honolulu, United States; 4BGI-Shenzhen, Shenzhen, China; 5China National GeneBank, BGI-Shenzhen, Shenzhen, China; 6Department of Biology, University of South Dakota, Vermillion, United States; 7Department of Biology, Faculty of Science, University of Zagreb, Zagreb, Croatia Abstract A widely accepted model for the evolution of cave animals posits colonization by surface ancestors followed by the acquisition of adaptations over many generations. However, the speed of cave adaptation in some species suggests mechanisms operating over shorter timescales. To address these mechanisms, we used Astyanax mexicanus, a teleost with ancestral surface morphs (surface fish, SF) and derived cave morphs (cavefish, CF). We exposed SF to completely dark conditions and identified numerous altered traits at both the gene expression and phenotypic levels. Remarkably, most of these alterations mimicked CF phenotypes. Our results indicate that many cave-related traits can appear within a single generation by phenotypic plasticity. In the next generation, plasticity can be further refined. The initial plastic responses are random in adaptive outcome but may determine the subsequent course of evolution. Our study suggests that phenotypic plasticity contributes to the rapid evolution of cave-related traits in A. mexicanus. *For correspondence: [email protected] Competing interests: The Introduction authors declare that no A major problem in modern biology is understanding how organisms adapt to an environmental competing interests exist.
    [Show full text]
  • Naše Jame Ourcaves 35/1
    1.0 km KARST REGIONS IN SLOVENIA NAŠE JAME 35/1 OURCAVES LJUBLJANA 1993 GLASILO JAMARSKE ZVEZE SLOVENIJE BULLETIN OF THE SPELEOLOG! CAL ASSOCIATION OF SLOVENIA NAŠE JAME OURCAVES Glasilo Jamarske zveze Slovenije Bulletin of the Speleological Association of Slovenia 35/1 * 1993 * Ljubljana Editorial Board Marko Aljančič /concept and editorial director/, Dr. Ivan Gams, Dr. Andrej Kranjc, Dr. France Leben, M.Sc. Dušan Novak /administration/, Tomaž Planina, Dr. Boris Sket, Stane Stražar, Dr. France Šušteršič, Dr. Janko Urbanc, Srečko Šajn. Translated by the authors and Mojca Urankar Cover drawn by Metka Karer Cover: Karst Regions in Slovenia Subscription assign to account of Administrative Office: LB 50100-678-0046103, Jamarska zveza Slovenije, 61109 Ljubljana, pp44 Printed by Planprint, Ljubljana Circulation: 800 copies Izdajo tega zvezka sta omogočili #nistrstvo za znanost in tehnologijo in rynnistrstvo za šolstvo in šport ISSN 0547-311X UDK- UDC 551.44(479.12) NAŠE JAME GLASILO JAMARSKE ZVEZE SLOVENIJE OURCAVES BULLETIN OF THE SPELEOLOG! CAL ASSOCIATION OF SLOVENIA 35/1, LJUBLJANA, 1993 CONTENTS Peter Habič Kras and karst in Slovenia ... .. ... ... ... .. .. ... .. ... .. .. .. .. ... .. .. ... .. ... .. .. .. 5 Dušan Novak Hydrogeological research of the Slovenian karst ......................................... ·.· 15 Ivan Gams Karstic denudation measurements in Slovenia and their geomorphological value ................................................................................... 31 France Leben Reflections of speleoarchaeology
    [Show full text]
  • The Role of Asellus Aquaticus on Organic Matter Degradation in Constructed Wetlands
    THE ROLE OF ASELLUS AQUATICUS ON ORGANIC MATTER DEGRADATION IN CONSTRUCTED WETLANDS Kim Baert Promotor: Prof. dr. ir. Peter Goethals Tutors: Natalia Donoso and Wout Van Echelpoel Master’s Dissertation submitted to Ghent University in partial fulfilment of the requirements for the degree of Master of Science in Bioscience Engineering: Environmental Technology Academiejaar: 2016 - 2017 Copyright The author and the promotor give the permission to use this thesis for consultation and to copy parts of it for personal use. Any other use is subject to the Laws of Copyright. Permission to produce any material contained in this work should be obtained from the author. Ghent, June 2017 The promotor The tutors The author Prof. ir. P. Goethals ir. Wout Van Echelpoel Msc. Natalia Donoso Kim Baert I II Acknowledgements I would like to thank the people without whom it would not have been possible to write this master thesis. First of all, I would like to give my gratitude to my promotor, prof. Goethals, for his confidence in me, his friendly support and good advices. I also really appreciate everything that my tutors, Natalia and Wout, have done for me. Natalia, you were a wonderful lab buddy! Thank you for the talks, your kindness and friendship, and the good support and guidance throughout this year. Wout, thank you for your excellent advices, your help with anything I didn’t know and your patience with me. Last but not least, I am very grateful to my parents, for always being there and for their listening ear and pep talks when I needed it.
    [Show full text]
  • Annotated Checklist of the Isopoda (Subphylum Crustacea: Class Malacostraca) of Arkansas and Oklahoma, with Emphasis Upon Subterranean Habitats
    1 Annotated Checklist of the Isopoda (Subphylum Crustacea: Class Malacostraca) of Arkansas and Oklahoma, with Emphasis Upon Subterranean Habitats G. O. Graening Department of Biological Sciences, California State University at Sacramento, Sacramento, CA 95819 Michael E. Slay Arkansas Field Office, The Nature Conservancy, 601 North University Avenue, Little Rock, AR 72205 Danté B. Fenolio Department of Biology, University of Miami, 1301 Memorial Drive, Coral Gables, FL 33124 Henry W. Robison Department of Biology, Southern Arkansas University, Magnolia, AR 71754 All known records of isopod crustaceans (Order Isopoda) in the states of Arkansas and Oklahoma are summarized, including new state, county, and site records. This updated checklist recognizes 47 taxa in 9 families: 2 taxa in Armadillidiidae; 1 in Armadillidae; 30 in Asellidae; 1 in Cylisticidae; 1 in Ligiidae; 1 in Oniscidae; 4 in Porcellionidae; 1 in Trachelipodidae; and 6 in Trichoniscidae. This faunal inventory includes 17 taxa that are subterranean obligates (troglobites or stygobites), and 14 taxa that are endemic to this geographical region. Current distributions and conservation statuses are summarized, and new rarity rankings are suggested. © 2007 Oklahoma Academy of Science INTRODUCTION these two states are closely associated with subterranean habitats, and those species This study assembles the first checklist restricted to hypogean habitats are typically of the entire Order Isopoda (Subphylum troglomorphic (i.e., exhibiting loss of pig- Crustacea: Class Malacostraca)
    [Show full text]