DOCSLIB.ORG

Cnidarian Diversity Phylum Cnidaria

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Cnidarian Diversity Phylum Cnidaria Cnidarian Diversity Phylum Cnidaria Class Class Class Class Anthozoa Hydrozoa Scyphozoa Cubozoa Corals Hydra True jellyfish Box jellies Anemones Portuguese Man-Of-War Sea wasps Stinging Limu Fire Coral General Characteristics of Cnidaria • Stinging cells • Two stages in life cycle (polyp & medusa) • Blind sack gut • Radial symmetry • Diploblastic • Hydrostatic skeleton • Nerve net • Many colonial, some solitary forms Class Hydrozoa • polyps and medusa stage, although polyp stage is dominant. • gut cavity of polyp is simple, lacking a pharynx and not divided by mesenteries. • tetramerous (four-part) radial symmetry. • gonads are ectodermal (found in the epidermis). • medusa stage may possess specialized balance organs called statocysts and photosensitive organs called ocelli. • solitary or colonials; some colonial forms highly polymorphic. • includes hydroids (“stinging limu”), fire coral, pink coral, and siphonophores –aka Portuguese man of War The Cnidarian Life Cycle The Hydrozoan Life Cycle Hydrozoan Colony Hydrozoan Medusa Fire Coral By-the-Wind-Sailor A Floating Colony of Polyps Coloniality Man-of-War Phylum Cnidaria Close Up of a Portuguese Man-Of-War Class Scyphozoa (Gr. skyphos, cup) • life cycle with both polyps and medusa, but medusa dominate with polyp stage reduced or absent. • polyp stage (scyphistoma) goes through strobilization to produce young medusa. • bell margin lacks a velum. • tetramerous (= four-part) radial symmetry. • gut divided into a complex system of radial canals. • some with a simple single mouth, but many with thousands of microscopic “mouths” at the ends of oral arms. • gonads endodermal (found in the gastrodermis). • specialized sense organs called rhopalia with ocelli & statocysts . • includes some 200 marine species. • "true" sea jellies. Scyphozoan Life Cycle strobila scyphistoma ephyra planula adult medusa gametes scyphistoma strobila Sea Jellies Moon Jelly Anatomy Class Cubozoa (Gr. kybos, a cube) • polyps and medusae stages, but medusae dominate with polyp stage reduced. • polyp stage develops directly into medusa. • bell margin with a velarium. • tetramerous (= four-part) radial symmetry; bell cube- shaped with tentacles arising from each corner. • gonads endodermal (found in the gastrodermis). • specialized sense organs called rhopalia with ocelli & statocysts . • includes some 15 marine species. • includes box jellies and sea wasps. Seawasp Box Jellies Box Jelly Anatomy Class Anthozoa (Gr. anthos, flower) • lack medusa stage entirely (polyp forms only) • mouth with a tubular pharynx that projects inward into the gut • large gut cavity divided by mesenteries that radiate inwards from the body wall • gonads endodermal, borne on the mesenteries • hexamerous (6-part) or octamerous (8-part) radial symmetry or biradial (modified radial symmetry that limits the number of planes that can divide the body into equal halves • includes sea anemones, “true” stony corals, sea fans, sea pens, organ pipe coral, precious black coral, & zoanthids Subclass Zoantharia Order Actinaria Sea Anemones Sea Anemone Anatomy Subclass Hexacorallia Order Zoanthidae Soft Corals • No hard skeleton • May be tough and leathery • Shallow water forms • Encrusting forms • Some with zooxanthellae • Polyp stage only Subclass Hexacorallia Order Scleractinia “True” Stony Corals Hermatypic- reef building, zooxanthellae Common species come in many different forms. These are real Reef Corals. “True” Stony Corals lobe finger mushroom Porites rus.
Load more

Recommended publications
  • Characterization of Translationally Controlled Tumour Protein from the Sea Anemone Anemonia Viridis and Transcriptome Wide Identification of Cnidarian Homologues
    G C A T T A C G G C A T genes Article Characterization of Translationally Controlled Tumour Protein from the Sea Anemone Anemonia viridis and Transcriptome Wide Identification of Cnidarian Homologues Aldo Nicosia 1,* ID , Carmelo Bennici 1, Girolama Biondo 1, Salvatore Costa 2 ID , Marilena Di Natale 1, Tiziana Masullo 1, Calogera Monastero 1, Maria Antonietta Ragusa 2, Marcello Tagliavia 1 and Angela Cuttitta 1,* 1 National Research Council-Institute for Marine and Coastal Environment (IAMC-CNR), Laboratory of Molecular Ecology and Biotechnology, Detached Unit of Capo Granitola, Via del mare, 91021 Torretta Granitola (TP), Sicily, Italy; [email protected] (C.B.); [email protected] (G.B.); [email protected] (M.D.N.); [email protected] (T.M.); [email protected] (C.M.); [email protected] (M.T.) 2 Department of Biological, Chemical and Pharmaceutical Sciences and Technologies, University of Palermo, Viale delle Scienze, Ed. 16, 90128 Palermo, Sicily, Italy; [email protected] (S.C.); [email protected] (M.A.R.) * Correspondence: [email protected] (A.N.); [email protected] (A.C.); Tel.: +39-0924-40600 (A.N. & A.C.) Received: 10 November 2017; Accepted: 5 January 2018; Published: 11 January 2018 Abstract: Gene family encoding translationally controlled tumour protein (TCTP) is defined as highly conserved among organisms; however, there is limited knowledge of non-bilateria. In this study, the first TCTP homologue from anthozoan was characterised in the Mediterranean Sea anemone, Anemonia viridis. The release of the genome sequence of Acropora digitifera, Exaiptasia pallida, Nematostella vectensis and Hydra vulgaris enabled a comprehensive study of the molecular evolution of TCTP family among cnidarians.
    [Show full text]
  • Resurrecting a Subgenus to Genus: Molecular Phylogeny of Euphyllia and Fimbriaphyllia (Order Scleractinia; Family Euphylliidae; Clade V)
    Resurrecting a subgenus to genus: molecular phylogeny of Euphyllia and Fimbriaphyllia (order Scleractinia; family Euphylliidae; clade V) Katrina S. Luzon1,2,3,*, Mei-Fang Lin4,5,6,*, Ma. Carmen A. Ablan Lagman1,7, Wilfredo Roehl Y. Licuanan1,2,3 and Chaolun Allen Chen4,8,9,* 1 Biology Department, De La Salle University, Manila, Philippines 2 Shields Ocean Research (SHORE) Center, De La Salle University, Manila, Philippines 3 The Marine Science Institute, University of the Philippines, Quezon City, Philippines 4 Biodiversity Research Center, Academia Sinica, Taipei, Taiwan 5 Department of Molecular and Cell Biology, James Cook University, Townsville, Australia 6 Evolutionary Neurobiology Unit, Okinawa Institute of Science and Technology Graduate University, Okinawa, Japan 7 Center for Natural Sciences and Environmental Research (CENSER), De La Salle University, Manila, Philippines 8 Taiwan International Graduate Program-Biodiversity, Academia Sinica, Taipei, Taiwan 9 Institute of Oceanography, National Taiwan University, Taipei, Taiwan * These authors contributed equally to this work. ABSTRACT Background. The corallum is crucial in building coral reefs and in diagnosing systematic relationships in the order Scleractinia. However, molecular phylogenetic analyses revealed a paraphyly in a majority of traditional families and genera among Scleractinia showing that other biological attributes of the coral, such as polyp morphology and reproductive traits, are underutilized. Among scleractinian genera, the Euphyllia, with nine nominal species in the Indo-Pacific region, is one of the groups Submitted 30 May 2017 that await phylogenetic resolution. Multiple genetic markers were used to construct Accepted 31 October 2017 Published 4 December 2017 the phylogeny of six Euphyllia species, namely E. ancora, E. divisa, E.
    [Show full text]
  • Anthozoa: Hexacorallia: Scleractinia: Dendrophylliidae) from Korea
    Anim. Syst. Evol. Divers. Vol. 32, No. 1: 38-43, January 2016 http://dx.doi.org/10.5635/ASED.2016.32.1.038 Short communication A New Record of Dendrophyllia compressa (Anthozoa: Hexacorallia: Scleractinia: Dendrophylliidae) from Korea Eunae Choi, Jun-Im Song* College of Natural Sciences, Ewha Womans University, Seoul 03760, Korea ABSTRACT Dendrophyllia compressa Ogawa and Takahashi, 1995 is newly reported from Korea. The specimen was collected off Seogwipo, Jeju-do, Korea in 1969. It is described herein based on the morphological characters of the skeletal structures. Dendrophyllia compressa is characterized by its small and bushy growth form with branches, vertical growth direction, small calicular diameter, compressed calice, Pourtalès Plan with vertical septal inner edges, flat and spongy columella, exserted septal upper margins, and epitheca. Dendrophyllia compressa has been synonymized with Cladopsammia eguchii (Wells, 1982). However, the former species differs from the latter species in its growth form, growth direction, colony size, corallite size, and corallite shape. Keywords: Anthozoa, Scleractinia, Dendrophylliidae, Dendrophyllia, Korea INTRODUCTION cribed. The specimen was collected from the subtidal zone off The family Dendrophylliidae Gray, 1847 comprises 167 Seogwipo, Jeju-do, Korea in 1969. It was dissolved in sod- species in 21 genera (Cairns, 2001; Roberts et al., 2009; ium hypochlorite solution diluted with distilled water for World Register of Marine Species, 2015). Among these 24 hours to remove all the soft tissues, washed in distilled species, 29 species in the genus Dendrophyllia have been water, and dried for the examination of the skeletal struc- reported worldwide (Roberts et al., 2009; World Register of tures. The external growth forms and shapes of the coralla Marine Species, 2015).
    [Show full text]
  • The Earliest Diverging Extant Scleractinian Corals Recovered by Mitochondrial Genomes Isabela G
    www.nature.com/scientificreports OPEN The earliest diverging extant scleractinian corals recovered by mitochondrial genomes Isabela G. L. Seiblitz1,2*, Kátia C. C. Capel2, Jarosław Stolarski3, Zheng Bin Randolph Quek4, Danwei Huang4,5 & Marcelo V. Kitahara1,2 Evolutionary reconstructions of scleractinian corals have a discrepant proportion of zooxanthellate reef-building species in relation to their azooxanthellate deep-sea counterparts. In particular, the earliest diverging “Basal” lineage remains poorly studied compared to “Robust” and “Complex” corals. The lack of data from corals other than reef-building species impairs a broader understanding of scleractinian evolution. Here, based on complete mitogenomes, the early onset of azooxanthellate corals is explored focusing on one of the most morphologically distinct families, Micrabaciidae. Sequenced on both Illumina and Sanger platforms, mitogenomes of four micrabaciids range from 19,048 to 19,542 bp and have gene content and order similar to the majority of scleractinians. Phylogenies containing all mitochondrial genes confrm the monophyly of Micrabaciidae as a sister group to the rest of Scleractinia. This topology not only corroborates the hypothesis of a solitary and azooxanthellate ancestor for the order, but also agrees with the unique skeletal microstructure previously found in the family. Moreover, the early-diverging position of micrabaciids followed by gardineriids reinforces the previously observed macromorphological similarities between micrabaciids and Corallimorpharia as
    [Show full text]
  • Coral Bleaching Early Warning Network Current Conditions Report #20090827
    Mote Marine Laboratory / Florida Keys National Marine Sanctuary Coral Bleaching Early Warning Network Current Conditions Report #20090827 Updated August 27, 2009 Summary: Based on climate predictions, current conditions, and field observations, the threat for mass coral bleaching within the FKNMS remains MODERATE. Weather and Sea Temperatures NOAA Coral Reef Watch Coral Bleaching Thermal Stress Outlook August -November, 2009 (Updated Aug. 25th) Figure 2. NOAA’s Coral Bleaching HotSpot Map for August 27, 2009. www.osdpd.noaa.gov/PSB/EPS/SST/climohot.html Figure 1. NOAA’s Coral Bleaching Thermal Stress Outlook for Aug. – Nov. 2009. According to the latest NOAA Coral Reef Watch Coral Bleaching Thermal Stress Outlook there continues to be significant potential for coral bleaching throughout the Caribbean in 2009 especially in the Lesser Antilles, with higher than normal thermal stress, reminiscent of that seen in 2005. (Fig. 1). Current remote sensing analysis by NOAA’s Coral Reef Watch program indicates that while the Florida Keys region continues to experience elevated levels of thermal stress, there has been no significant increase in those levels over the past two weeks. NOAA’s recent Coral Bleaching HotSpot Map (Fig. 2), which provides current SST’s compared to the historically expected SST’s for the region, shows that temperature anomalies for the Florida Keys National Marine Sanctuary and surrounding waters continue to remain above-average but have decreased slightly since Figure 3. NOAA’s Degree Heating Weeks Map for August 27, 2009. mid-August. Similarly, NOAA’s latest Degree Heating Weeks (DHW) www.osdpd.noaa.gov/PSB/EPS/SST/dhw_retro.html map, which illustrates the accumulation of elevated temperature in an area Water Temperatures (August 13-27, 2009) based on the previous 12 weeks, indicates that cumulative temperature 35 stress in the Florida Keys region remains elevated but has not increased significantly over the past two weeks (Fig.
    [Show full text]
  • The Aquaculture of Live Rock, Live Sand, Coral and Associated Products
    AQUACULTURE OF LIVE ROCKS, LIVE SAND, CORAL AND ASSOCIATED PRODUCTS A DISCUSSION AND DRAFT POLICY PAPER FISHERIES MANAGEMENT PAPER NO. 196 Department of Fisheries 168 St. Georges Terrace Perth WA 6000 April 2006 ISSN 0819-4327 The Aquaculture of Live Rock, Live Sand, Coral and Associated Products A Discussion and Draft Policy Paper Project Managed by Andrew Beer April 2006 Fisheries Management Paper No. 196 ISSN 0819-4327 Fisheries Management Paper No. 196 CONTENTS OPPORTUNITY FOR PUBLIC COMMENT...............................................................IV DISCLAIMER V ACKNOWLEDGEMENT..................................................................................................V SECTION 1 EXECUTIVE SUMMARY & PROPOSED POLICY OPTIONS ....... 1 SECTION 2 INTRODUCTION.................................................................................... 5 2.1 BACKGROUND ............................................................................................. 5 2.2 OBJECTIVES................................................................................................. 5 2.3 WHY LIVE ROCK, SAND AND CORAL AQUACULTURE? ............................... 6 2.4 MARKET...................................................................................................... 6 SECTION 3 THE TAXONOMY AND BIOLOGY OF LIVE ROCK, SAND AND CORAL ..................................................................................................... 9 3.1 LIVE ROCK .................................................................................................
    [Show full text]
  • Target Substrata
    TARGET SUBSTRATA OVERVIEW CORALS AND THEIR RELATIVES STONY HEXACORALS OTHER HEXACORALS OCTOCORALS HYDROZOANS Acropora Sea Anemones Soft Corals Fire Coral Non-Acropora Zoanthids Sea Fans Lace Coral Black Coral Blue Coral Hydroids Corallimorpharians Organ Pipe OTHER SUBSTRATA Sponge Macroalgae Dead Coral Rock Coralline Algae Dead Coral With Algae Rubble Algal Assemblage Turf Algae Sand Silt CORALS AND THEIR RELATIVES STONY CORALS ACROPORA Phylum Cnidaria | Class Anthozoa | Sub-Class Hexacorallia | Order Scleractinia (Hard Corals) | Family Acroporidae | Genus Acropora Acropora is one genus within the family of Acroporidae; Generally, the species are characterized by the presence of an axial (terminal) corallite (skeleton of an individual polyp) at the branch tips surrounded by radial corallites; The name Acropora is derived from the Greek “akron” which means summit. Acropora Branching Barefoot Conservation | TARGET SUBSTRATA | July 2016 1 Acropora Bottlebrush Acropora Digitate Acropora Tabulate Barefoot Conservation | TARGET SUBSTRATA | July 2016 2 Acropora Submassive Acropora Encrusting Non-Acropora Phylum Cnidaria | Class Anthozoa | Sub-Class Hexacorallia | Order Scleractinia (Hard Corals) | Family Acroporidae Coral Branching Barefoot Conservation | TARGET SUBSTRATA | July 2016 3 (continued) Coral Branching Coral Massive Barefoot Conservation | TARGET SUBSTRATA | July 2016 4 Coral Encrusting Coral Foliose Coral Submassive Barefoot Conservation | TARGET SUBSTRATA | July 2016 5 (continued) Coral Submassive Coral Mushroom Barefoot Conservation
    [Show full text]
  • Zoanthid (Cnidaria: Anthozoa: Hexacorallia: Zoantharia) Species of Coral Reefs in Palau
    Mar Biodiv DOI 10.1007/s12526-013-0180-5 ORIGINAL PAPER Zoanthid (Cnidaria: Anthozoa: Hexacorallia: Zoantharia) species of coral reefs in Palau James Davis Reimer & Doris Albinsky & Sung-Yin Yang & Julien Lorion Received: 3 June 2013 /Revised: 16 August 2013 /Accepted: 20 August 2013 # Senckenberg Gesellschaft für Naturforschung and Springer-Verlag Berlin Heidelberg 2013 Abstract Palau is world famous for its relatively pristine and Introduction highly diverse coral reefs, yet for many coral reef invertebrate taxa, few data exist on their diversity in this Micronesian coun- Palau is located at the southwestern corner of Micronesia, and try. One such taxon is the Zoantharia, an order of benthic is just outside the Coral Triangle, the region with the highest cnidarians within the Class Anthozoa (Subclass Hexacorallia) marine biodiversity in the world (Hoeksema 2007). Thus, Palau that are commonly found in shallow subtropical and tropical is an important link between the central Indo-Pacific and the waters. Here, we examine the species diversity of zoanthids in Pacific Islands, and diversity and distribution data of marine Palau for the first time, based on shallow-water (<35 m) scuba organisms from Palau can help us to understand the evolutionary surveys and morphological identification to create a preliminary and biogeographical history of the region. Because of Palau’s zoanthid species list for Palau. Our results indicated the presence combination of a high habitat diversity with a close proximity to of nine zoanthid species in Palau (Zoanthus sansibaricus, Z. the Coral Triangle, it has the most diverse marine flora and fauna gigantus, Palythoa tuberculosa, P. mutuki, P.
    [Show full text]
  • Status of Coral Reefs of the World: 2002
    Status of Coral Reefs of the World: 2002 Edited by Clive Wilkinson PDF compression, OCR, web optimization using a watermarked evaluation copy of CVISION PDFCompressor Dedication This book is dedicated to all those people who are working to conserve the coral reefs of the world – we thank them for their efforts. It is also dedicated to the International Coral Reef Initiative and partners, one of which is the Government of the United States of America operating through the US Coral Reef Task Force. Of particular mention is the support to the GCRMN from the US Department of State and the US National Oceanographic and Atmospheric Administration. I wish to make a special dedication to Robert (Bob) E. Johannes (1936-2002) who has spent over 40 years working on coral reefs, especially linking the scientists who research and monitor reefs with the millions of people who live on and beside these resources and often depend for their lives from them. Bob had a rare gift of understanding both sides and advocated a partnership of traditional and modern management for reef conservation. We will miss you Bob! Front cover: Vanuatu - burning of branching Acropora corals in a coral rock oven to make lime for chewing betel nut (photo by Terry Done, AIMS, see page 190). Back cover: Great Barrier Reef - diver measuring large crown-of-thorns starfish (Acanthaster planci) and freshly eaten Acropora corals (photo by Peter Moran, AIMS). This report has been produced for the sole use of the party who requested it. The application or use of this report and of any data or information (including results of experiments, conclusions, and recommendations) contained within it shall be at the sole risk and responsibility of that party.
    [Show full text]
  • Natural Resource Utilisation and Environmental Preservation: Issues
    Natural Resource Utilisation and Environmental Preservation: Issues and Challenges 20 Proceedings of Second Regional Symposium on Environment and Natural Resources, Vol:2 22-23 March 2005, Pan Pacific Hotel, Kuala Lumpur, Malaysia SCLERACTINIAN CORAL DIVERSITY OF KG TEKEK, PULAU TIOMAN MARINE PARK AFFENDI YANG AMRI1, BADRUL HUZAIMI TAJUDDIN1, LEE YOKE LEE2, KEE ALFIAN ABD. ADZIS3 AND YUSRI YUSUF4 1Institute of Biological Sciences, Universiti Malaya, 50603 Kuala Lumpur 2WWF-Malaysia, 49, Jalan SS23/15, Taman SEA, 47400 Petaling Jaya, Selangor 3Universiti Kebangsaan Malaysia, Bangi, Selangor 4ReefBase, The World Fish Center, Jalan Batu Maung, 11960 Bayan Lepas, Penang Correspondence email: [email protected] ABSTRACT The reef situated adjacent to Kg. Tekek, Pulau Tioman Marine Park was surveyed during the months of August to October 2004 to document the diversity of hard corals (scleractinian corals) found there. We did random swims using SCUBA along the reef while taking notes of each coral colony morphology and growth forms. Additional underwater close-up digital photography of corallites on each colony was also done. Coral species identification were referenced using Veron & Stafford-Smith (2000). Compared to a study by Harborne et al. (2000) of the waters around Pulau Tioman which found 183 species, this study found a total of 221 hard coral species from 14 families. The dominant families were Acroporidae (59 species), Faviidae (52 species) and Fungiidae (27 species). In addition seventeen species that are categorised by Veron & Stafford-Smith (2000) to be rare worldwide were found in the study area. We believe that the study area is very unique, important as a pool for coral species and needs to be managed with great care.
    [Show full text]
  • A Guide to the Identification of the Common Corals of St. Croix
    A Guide to the Identification of the Common Corals of St. Croix Thomas Suchanek Department of Biology University of California Davis, CA Converted to digital format by Thomas F. Barry (NOAA/RSMAS) in 2004. Copy available at the NOAA Miami Regional Library. Minor editorial changes may have been made. Guide to the Common Corals of St. Croix 197 A Guide to the Identification of the Common Corals of St. Croix Thomas Suchanek Dept. of Biology University of California Davis, CA INTRODUCTION This guide was designed as an aid in identifying both live and dead corals from St. Croix which form hard, calcium carbonate skeletons. This encompasses representatives both from the Class Anthozoa (the true or scleractinian corals) and from the Class Hydrozoa (hydrocorals). Representatives from the third class of Cnidaria, the Scyphozoa, produce no calcium carbonate skeletons and are not discussed. Of the 60 or so species of "stony" corals found in the western Atlantic region, this guide focuses on 37 species which are found relatively commonly on St. Croix. Other representatives which may be common in other locations such as St. Thomas, Puerto Rico, Jamaica or Florida, but are not common on St. Croix, have not been included. Various references listed at the end of the text include many of those other species. The guide is arranged in two sections. First is a descriptive section including taxonomic and natural history information on each species represented. Following that section is a series of plates which depict three conditions for each species. First is a habitat photo, as the coral colony would appear to a swimmer or diver approaching it in the field.
    [Show full text]
  • Aquaculture of Coral, Live Rocks and Associated Products
    AQUACULTURE OF CORAL, LIVE ROCKS AND ASSOCIATED PRODUCTS Aquaculture Policy FISHERIES MANAGEMENT PAPER NO. 245 Published by Department of Fisheries 168 St. Georges Terrace Perth WA 6000 August 2009 ISSN 0819-4327 The Aquaculture of Coral, Live Rocks and Associated Products Aquaculture Policy August 2009 Fisheries Management Paper No. 245 ISSN 0819-4327 ii Fisheries Management Paper No.245 CONTENTS DISCLAIMER...................................................................................................................... iv ACKNOWLEDGEMENT ................................................................................................... iv EXECUTIVE SUMMARY ................................................................................................. 1 SECTION 1 INTRODUCTION ........................................................................................ 2 SECTION 2 BACKGROUND .......................................................................................... 3 2.1 What is Coral? ...................................................................................................... 3 2.1.1 Stony Corals .......................................................................................... 3 2.1.2 Soft Corals ............................................................................................. 5 2.1.3 False Corals and Coral Anemones – the Coralliomorphs ...................... 6 2.1.4 Button Polyps – the Zoanthids ............................................................... 6 2.2 What are Live Rock and
    [Show full text]