DOCSLIB.ORG

Histological Investigation of the Digestive System and SEM Study of Radula in Fusinus Nicobaricus (Gastropoda: Fasciolariidae)

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Histological Investigation of the Digestive System and SEM Study of Radula in Fusinus Nicobaricus (Gastropoda: Fasciolariidae) B-3759 [1-5] Indian J. Anim. Res., AGRICULTURAL RESEARCH COMMUNICATION CENTRE Print ISSN:0367-6722 / Online ISSN:0976-0555 www.arccjournals.com Histological Investigation of the Digestive System and SEM Study of Radula in Fusinus nicobaricus (Gastropoda: Fasciolariidae) P. Subavathy* PG and Research Department of Zoology, St. Mary’s College (Autonomous), Thoothukudi Affiliated to Manonmaniam Sundaranar University, Abishekapatti, Tirunelveli-627 012, Tamil Nadu, India. Received: 26-11-2018 Accepted: 15-10-2019 ABSTRACT In the present study, histological studies of the digestive system and SEM study of radula of Fusinus nicobaricus was evaluated. The digestive system contains proboscis, oesophagus, stomach, hepatopancreas, intestine, rectum and anus. The digestive tract of Fusinus nicobaricus encloses a buccal mass at the anterior region which contains a chitinous radula. The oesophagus leaved the buccal mass dorsally and passed the food into an extensible stomach. A pair of salivary gland lied with mid-oesophagus region. Digestive gland secreted digestive enzymes into the lumen of the stomach into mid region. Intestine was thin walled, usually long and possess loop through the digestive gland tissue and leaves as short rectum. Hepatopancreas was also implicated in storage and excretion of inorganic reserves, lipids and carbohydrate metabolites. Radula, a specific character and part of the appendices of digestive system of majority of molluscs. It was observed that the type of radula in F.n is rachiglossate with radular formula of 1+R+1. Key words: Fusinus nicobaricus, Hepatopancreas, Oesophagus, Radula, Rectum. INTRODUCTION in a longitudinal ribbon of transverse rows (Ramesh and Marine fauna comprises of several phyla, orders, Ravichandran, 2008). classes, families, genera and species. Among the various Scanning electron microscope is the powerful tool phyla represented in the marine environment, the phylum in radular study. Research on functional morphology of Mollusca is the second largest phylum in the animal kingdom molluscan radula has focussed attention on the obvious food next to Arthropoda (Abbott, 1954). Gastropods evolved on preparing and food-gathering operation of teeth and their rocky marine bottoms but have radiated into a wide variety relationship. The scanning electron microscope permits the of other habitats. Fusinus nicobaricus comes under the family examination of radula with higher magnification without fasciolariidae and sub-family fusininae. They are carnivores, elaborate preliminary preparation and without squashing or feeding on worms and clams. fragmentation. A clear picture of three-dimensional Virtually every possible feeding mode is found in morphology can therefore be obtained, which enlightens gastropods and the morphology and physiology of the more mundane methods of observation. The radula has been digestive system vary widely (Hyman, 1967).The gastropoda frequently investigated because of its importance as a tool are remarkable for their feeding mechanisms and for the wide in supraspecific systematics to diagnose the species. The variety of food they subsist. The feeding habits and food shape of the radula teeth is directly related to the kind of preference do not form a distinctive part of a particular group. food, which the animals eat and the way in which it is Thus, the prosobranchia in particular, displays almost every manipulated. The length of the radula also appears to be conceivable food preference. related to the quantum of work, which has to be done in Another peculiar feature of mollusc is the presence feeding (Reid and Mak, 1999). In the present study an attempt of a chitinous radula. Purchon (1977) stated that the adaptive was made to elucidate the histological studies of digestive radiation of the gastropoda is principally based on system and anatomy of the radulae of Fusinus nicobaricus adaptations of the buccal mass and radula to meet the from the Gulf of Mannar region. problems faced in feeding in various ways on a wide variety MATERIALS AND METHODS of food substances. In most gastropods the radula is a highly Specimens of Fusinus nicobaricus used in the developed feeding organ that acts as a grater, rasp, brush present study were collected during low tides from the sea cutter, grasper, harpoon or conveyor. Total number of teeth in their natural habitat that is intertidal zone, from reefs by varies from 16 to thousands and is almost always arranged divers and from trawl nets used for crab fishing from Gulf *Corresponding author’s e-mail: [email protected] 2 INDIAN JOURNAL OF ANIMAL RESEARCH of Mannar coastal region. They were brought to the electron microscope specimen chamber and heating the laboratory and maintained under laboratory conditions for conductive metal (gold) to the point of vapourization. A small further observations. Preserved specimens were not used for part of the cloud of metallic vapour hits the surface of the anatomical study of digestive system as they lose their object and sticks to it so as to provide a thin metallic coating original colour due to preservation. Additionally, the organs over it. Continuous tiltation and rotation of the specimen may show considerable shrinkage. Freshly killed specimens ensures that the metallic vapour covers all sides of the were used for the study of digestive system. Measurements specimen. Then the specimens were mounted to SEM stub were made using ocular and stage micrometers. Camera and the observations were made with different magnifications lucida drawings were made with the help of a stereo-zoom for making the electron micrographs by using JEOC JSM microscope. 35CF scanning electron microscope (Annamalai University, Histological studies of the digestive system: For Chidambaram). histological studies, the tissue samples were taken from RESULTS AND DISCUSSION proboscis, oesophagus, stomach, hepatopancreas, intestine Histological studies of the digestive system of Fusinus and rectum. These different soft tissues were fixed in aqueous nicobaricus: The digestive system of Fusinus nicobaricus Bouins and Zenker’s solution. Sections of 6-8mthickness contains proboscis, oesophagus, stomach, hepatopancreas, were made from different organs and stained in delafield intestine, rectum and anus.The general organization of hemotoxylin with eosin as a counter stain. digestive system of Fusinus nicobaricus, follow the same SEM study of radula: For scanning electron microscope general pattern of neogastropod. The cellular organization study of radula, the anterior portion of the proboscis was of the various body parts of Fusinus nicobaricus, excised, the radula with adjoining tissues were removed from histologically proved the same functional significance as the proboscis and boiled with alkaline iodide solution until encountered in other Fasciolarids.The digestive system in the dissolution of all the muscle fibers attached to the radula. the Fasciolaria Fusinus nicobaricus begun with the The radula thus obtained was then dehydrated by immersing pleurembolic type of proboscis and the rachiglossate type them in increasing concentration of alcohol (50, 70, 90 and of radula (Fig 1-3) similar to that of Thais sp, Muricanthus 100%). Then the dehydrated radula was prepared with sp, Uro sucpinx sp (Kool,1993). coating for making it suitable for scanning electron Proboscis: The most conspicuous features of the digestive microscopical observation. system was the massive proboscis. In Fusinus nicobaricus Principally coating of the radula consists of placing the proboscis was a large, yellowish organ and of the specimen in a vacuum evaporator pumping the chamber pleurembolic type in which the basal part was invaginable down to a vacuum level equivalent to that in the scanning (Fig 1a). When the proboscis invaginated, it retracted the (a) (b ) (c) Fig 1: (a) Proboscis – Cross section through proboscis of Fusinus nicobaricus showing the histological organization of columnar ciliated cells, radula tooth and odontophore (4x). (b) Oesophagus – Cross section through the oesophagus of Fusinus nicobaricus showing the histological organization of ciliated columnar epithelium, lumen and basement membrane (4x). (c) Stomach – Cross section through the stomach of Fusinus nicobaricus showing the histological organization of ciliated columnar epithelium and connective tissue (4x). Vol. Issue , () distal part into a proboscis sheath. The mouth lied at the and muscle fibres were embedded in the stomach of Fusinus anterior end of the proboscis. The odontophore and the radula nicobaricus (Fig 1c). sac lied within the proboscis.The proboscis of Fusinus Intestine: The intestine was a tubular structure arised from nicobaricus was similar to the description of the proboscis the distal part of the stomach. The intestine had a wall of its of Thais species by Tagore (1989), Rapana rapiformis by own, till it enters the mantlle cavity. It ran forward adjacent Rajakumar (1995), Babylonia spirata by Thilaga (2005) and to the kidney. It was attached to the mantle as it nears the Chicoreus virgineus by Sharmila (2009). mantle cavity and was surrounded by connective tissue. The Oesophagus: The oesophagus which followed the buccal intestine was smooth leading out from stomach. mass was long in Fusinus nicobaricus. The oesophageal Histologically the intestine showed finger-like projections region was complicated and divided into anterior, mid and inside the intestinal wall lined by ciliated cells and glandular posterior oesophagus. A pair of salivary glands were cells
Load more

Recommended publications
  • Histological Changes and Biochemical Parameters in the Hepatopancreas of Terrestrial Gastropod Helix Aspersa As Biomarkers of Neonicotinoid Insecticide Exposure
    African Journal of Biotechnology Vol. 11(96), pp. 16277-16283, 29 November, 2012 Available online at http://www.academicjournals.org/AJB DOI: 10.5897/AJB12.1696 ISSN 1684–5315 ©2012 Academic Journals Full Length Research Paper Histological changes and biochemical parameters in the hepatopancreas of terrestrial gastropod Helix aspersa as biomarkers of neonicotinoid insecticide exposure Smina Ait Hamlet1*, Samira Bensoltane1,2, Mohamed Djekoun3, Fatiha Yassi2 and Houria Berrebbah1 1Cellular Toxicology Laboratory, Department of Biology, Faculty of Sciences, Badji-Mokhtar University, Annaba, P.O. Box 12, 23000, Algeria. 2Faculty of Medicine, Badji-Mokhtar University, Annaba, 23000, Algeria. 3Department of Biology, Faculty of Sciences and the Universe, University of May 08th, 1945, Guelma, 24000, Algeria. Accepted 22 June, 2012 In this study, adult snails, Helix aspersa were used to estimate the effect of aneonicotinoid insecticide (thiametoxam) on biochemical parameters and histological changes in the hepatopancreas of this gastropod after a treatment of six weeks. During this period, snails were exposed by ingestion and contact to fresh lettuce leaves which were soaked with an insecticide solution. The thiametoxam test solutions were 0, 25, 50, 100 and 200 mg/L. The results of the biochemical dosages (total carbohydrates, total proteins and total lipids) showed significant decreases at two concentrations (100 and 200 mg/L) of thiametoxam. However, the histological examination of the hepatopancreas of the treated snails showed alterations as a response to all the treatments, and revealed the degeneration of the digestive tubules and the breakdown of the basement membrane in a dose-dependent manner, leading to a severe deterioration of the tissues in the concentration of 200 mg/L thiametoxam.
    [Show full text]
  • Copyrighted Material
    319 Index a oral cavity 195 guanocytes 228, 231, 233 accessory sex glands 125, 316 parasites 210–11 heart 235 acidophils 209, 254 pharynx 195, 197 hemocytes 236 acinar glands 304 podocytes 203–4 hemolymph 234–5, 236 acontia 68 pseudohearts 206, 208 immune system 236 air sacs 305 reproductive system 186, 214–17 life expectancy 222 alimentary canal see digestive setae 191–2 Malpighian tubules 232, 233 system taxonomy 185 musculoskeletal system amoebocytes testis 214 226–9 Cnidaria 70, 77 typhlosole 203 nephrocytes 233 Porifera 28 antennae nervous system 237–8 ampullae 10 Decapoda 278 ocelli 240 Annelida 185–218 Insecta 301, 315 oral cavity 230 blood vessels 206–8 Myriapoda 264, 275 ovary 238 body wall 189–94 aphodus 38 pedipalps 222–3 calciferous glands 197–200 apodemes 285 pharynx 230 ciliated funnel 204–5 apophallation 87–8 reproductive system 238–40 circulatory system 205–8 apopylar cell 26 respiratory system 236–7 clitellum 192–4 apopyle 38 silk glands 226, 242–3 coelomocytes 208–10 aquiferous system 21–2, 33–8 stercoral sac 231 crop 200–1 Arachnida 221–43 sucking stomach 230 cuticle 189 biomedical applications 222 taxonomy 221 diet 186–7 body wall 226–9 testis 239–40 digestive system 194–203 book lungs 236–7 tracheal tube system 237 dissection 187–9 brain 237 traded species 222 epidermis 189–91 chelicera 222, 229 venom gland 241–2 esophagus 197–200 circulatory system 234–6 walking legs 223 excretory system 203–5 COPYRIGHTEDconnective tissue 228–9 MATERIALzoonosis 222 ganglia 211–13 coxal glands 232, 233–4 archaeocytes 28–9 giant nerve
    [Show full text]
  • Biology and Description of Antisabia Juliae Sp. Nov., New Hipponicid Gastropod Commensal on Turbo Spp
    SCI. MAR., 61 (Supl. 2): 5-14 SCIENTIA MARINA 1997 ECOLOGY OF MARINE MOLLUSCS. J.D. ROS and A. GUERRA (eds.) Biology and description of Antisabia juliae sp. nov., new Hipponicid gastropod commensal on Turbo spp. in Laing Island (Papua New Guinea)* MATHIEU POULICEK1, JEAN-CLAUDE BUSSERS1 and PIERRE VANDEWALLE2 1Animal Ecology Laboratory and 2Functional Morphology Laboratory, Zoological Institute, Liège University. 22, Quai Van Beneden, B-4020 Liège. Belgium. SUMMARY: The gastropod family Hipponicidae comprises widely distributed but poorly known sedentary species. On the beach-rock of the coral reefs of Laing Island (Papua New Guinea) live rich populations of several gastropod Turbo species of which many specimens have attached to their shell a hipponicid gastropod attributed to a new species, Antisabia juliae. This new species, described in this paper, appears to have adapted its mode of life on live turbinids in several ways result- ing in morphological changes (thin basal plate loosely adherent to the supporting shell, functional eyes, very long snout, functional radula, small osphradium) and ethological changes (foraging behaviour: it appears to feed on the epiphytic com- munity growing on the host, in the vicinity of the “host” shell). Except for these characteristics, the mode of life appears quite similar to that of other hipponicid species with few big females surrounded by several much smaller males. Development occurs within the egg mass inside the female shell and a few young snails escape at the crawling stage. Key words: Mollusca, Gastropoda, ecology, Hipponicidae, Papua New Guinea, Indopacific. RESUMEN: BIOLOGÍA Y DESCRIPCIÓN DE ANTISABIA JULIAE SP. NOV., UN NUEVO GASTERÓPODO HIPONÍCIDO COMENSAL DE TURBO SPP.
    [Show full text]
  • Mir-29A Participated in Nacre Formation and Immune Response by Targeting Y2R in Pinctada Martensii
    Article miR-29a Participated in Nacre Formation and Immune Response by Targeting Y2R in Pinctada martensii Rongrong Tian 1, Zhe Zheng 1, Ronglian Huang 1, Yu Jiao 1,* and Xiaodong Du 1,2,* Received: 17 September 2015; Accepted: 1 December 2015; Published: 10 December 2015 Academic Editor: Constantinos Stathopoulos 1 Fishery College, Guangdong Ocean University, Zhanjiang 524025, China; [email protected] (R.T.); [email protected] (Z.Z.); [email protected] (R.H.) 2 Guangdong Technology Research Center for Pearl Aquaculture and Process, Guangdong Ocean University, Zhanjiang 524025, China * Correspondence: [email protected] (Y.J.); [email protected] (X.D.); Tel.: +86-759-238-3346 (Y.J. & X.D.); Fax: +86-759-238-2404 (Y.J. & X.D.) Abstract: miR-29a is a conserved miRNA that participates in bone formation and immune response in vertebrates. miR-29a of Pinctada martensii (Pm-miR-29a) was identified in the previous research though deep sequencing. In this report, the precise sequence of mature Pm-miR-29a was validated using miRNA rapid amplification of cDNA ends (miR-RACE) technology. The precursor sequence of Pm-miR-29a was predicted to have 87 bp. Stem loop qRT-PCR analysis showed that Pm-miR-29a was easily detected in all the tissues, although expressions in the mantle and gill were low. The microstructure showed the disrupted growth of the nacre after Pm-miR-29a over-expression, which was induced by mimic injection into P. martensii. Results of the target analysis indicated that neuropeptide Y receptor type 2 (Y2R) was the potential target of Pm-miR-29a. Meanwhile, Pm-miR-29a mimics could obviously inhibit the relative luciferase activity of the reporter containing 31 UTR (Untranslated Regions) of the Y2R gene.
    [Show full text]
  • Annelids, Arthropods, Molluscs 2. Very Diverse, Mostly Marine B. Characteristics 1
    Molluscs A. Introduction 1. Three big Protostome Phyla - Annelids, Arthropods, Molluscs 2. Very diverse, mostly marine B. Characteristics 1. Bilateral symmetrical, unsegmented with definite head 2. Muscular foot 3. Mantle - mantle cavity a. Secretes shell - Calcium carbonate 4. Ciliated epithelium 5. Coelom reduced - around heart 6. Open circulatory system 7. Gaseous exchange by gills, lung, or just body surface 8. Metanephridia - empty into mantle cavity C. Body Plan 1. Generalized mollusc a. Mantle - secreted shell b. Mantle - cavity has gills - posterior - location important 2. Head-foot a. Head - 1. Radula - rasping tongue a. Mostly for scraping - snails b. Some (Cone shells) modified to a dart and poison b. Foot - Variously modified 1. Ventral sole-like structure - movement 2. May be shaped for burrowing 3. Shell 1. Made of Calcium Carbonate Molluscs 2. Three layers a. Periostracum - organic layer - not always visible b. Prismatic layer - prim-shaped crystals of calcium carbonate 1. Secreted by gladular margin of mantle 2. Grows as animal grows c. Nacreous layer 1. Continuously secreted by mantle on interior of shell 2. Pearls 4. Reproduction a. Larval stages 1. Trochophore - first stage to hatch from egg 2. Veliger - planktonic larva of most marine snails and bivalves a. Beginnings of foot, shell and mantle D. Classes - problem of segmentation - is it the original body plan - have molluscs lost segementation? 1. Monoplacophora - genus Neopilina a. Serial repetition in body form b. Single shell c. Interesting story of discovery 2. Polyplacophora - chitons a. Segmented shell - plates b. Multiple gills down side of body - not like generalized plan c. Rock dwellers that use radula to scrape algae off rocks 3.
    [Show full text]
  • Mollusca Three Classes
    Mollusca Three Classes 1. Gastropoda (gastropods)~ slugs and snails 2. Bivalvia (bivalves) ~ clams and other two- shelled shellfish 3. Cephalopoda (cephalopods) ~ squids, octopuses and cuttlefish 1 Bodies of Mollusks • A mollusk has a soft body which is usually covered by a hard outer shell. • Exceptions: – Slugs and octopuses have lost their shells through evolution – Squids have very reduced shells Anatomy of a Mollusk • All mollusks have: – Foot ~ the muscular foot helps it move – Visceral mass ~ contains the gills, gut, and other organs – Mantle ~ covers the visceral mass to protect the mollusks without shells • Most mollusks have: – Shell ~ protects the mollusk from predators and keeps land mollusks from drying out. 2 Symmetry of Mollusks • Mollusks have bilateral symmetry. – The two halves of the body mirror each other. Anatomy of a Snail (gastropod) 3 Anatomy of a Clam (bivalve) Anatomy of a Squid (cephalopod) 4 Eating Behaviors • Bivalves (clams) ~ filter tiny plant and bacteria from the water • Gastropods (snails) ~ eat with a radula (tiny tongue covered with teeth. – The radula is used to scrape algae off rocks and pieces of leaves and seaweed • Cephalopods (squid) ~use tentacles to grab their prey and put it in their powerful jaws. Blue-ringed octopus 5 Market Squid Moon Snail chasing its food 6 Achatina fulica Giant African Land Snail The largest land snail known is the Giant African Land Snail. It can weigh up to 2 pounds and be 15 inches long. Commonly Eaten Mollusks cockles conch oysters clams scallops abalone whelks Mussels Pen shells 7.
    [Show full text]
  • Brief Glossary and Bibliography of Mollusks
    A Brief Glossary of Molluscan Terms Compiled by Bruce Neville Bivalve. A member of the second most speciose class of Mollusca, generally bearing a shell of two valves, left and right, and lacking a radula. Commonly called clams, mussels, oysters, scallops, cockles, shipworms, etc. Formerly called pelecypods (class Pelecypoda). Cephalopoda. The third dominant class of Mollusca, generally without a true shell, though various internal hard structures may be present, highly specialized anatomically for mobility. Commonly called octopuses, squids, cuttles, nautiluses. Columella. The axis, real or imaginary, around and along which a gastropod shell grows. Dextral. Right-handed, with the aperture on the right when the spire is at the top. Most gastropods are dextral. Gastropod. A member of the largest class of Mollusca, often bearing a shell of one valve and an operculum. Commonly called snails, slugs, limpets, conchs, whelks, sea hares, nudibranchs, etc. Mantle. The organ that secretes the shell. Mollusk (or mollusc). A member of the second largest phylum of animals, generally with a non-segmented body divided into head, foot, and visceral regions; often bearing a shell secreted by a mantle; and having a radula. Operculum. A horny or calcareous pad that partially or completely closes the aperture of some gastropodsl. Periostracum. The proteinaceous layer covering the exterior of some mollusk shells. Protoconch. The larval shell of the veliger, often remains as the tip of the adult shell. Also called prodissoconch in bivlavles. Radula. A ribbon of teeth, unique to mollusks, used to procure food. Sinistral. Left-handed, with the aperture on the left when the spire is at the top.
    [Show full text]
  • Mollusca, Archaeogastropoda) from the Northeastern Pacific
    Zoologica Scripta, Vol. 25, No. 1, pp. 35-49, 1996 Pergamon Elsevier Science Ltd © 1996 The Norwegian Academy of Science and Letters Printed in Great Britain. All rights reserved 0300-3256(95)00015-1 0300-3256/96 $ 15.00 + 0.00 Anatomy and systematics of bathyphytophilid limpets (Mollusca, Archaeogastropoda) from the northeastern Pacific GERHARD HASZPRUNAR and JAMES H. McLEAN Accepted 28 September 1995 Haszprunar, G. & McLean, J. H. 1995. Anatomy and systematics of bathyphytophilid limpets (Mollusca, Archaeogastropoda) from the northeastern Pacific.—Zool. Scr. 25: 35^9. Bathyphytophilus diegensis sp. n. is described on basis of shell and radula characters. The radula of another species of Bathyphytophilus is illustrated, but the species is not described since the shell is unknown. Both species feed on detached blades of the surfgrass Phyllospadix carried by turbidity currents into continental slope depths in the San Diego Trough. The anatomy of B. diegensis was investigated by means of semithin serial sectioning and graphic reconstruction. The shell is limpet­ like; the protoconch resembles that of pseudococculinids and other lepetelloids. The radula is a distinctive, highly modified rhipidoglossate type with close similarities to the lepetellid radula. The anatomy falls well into the lepetelloid bauplan and is in general similar to that of Pseudococculini- dae and Pyropeltidae. Apomorphic features are the presence of gill-leaflets at both sides of the pallial roof (shared with certain pseudococculinids), the lack of jaws, and in particular many enigmatic pouches (bacterial chambers?) which open into the posterior oesophagus. Autapomor- phic characters of shell, radula and anatomy confirm the placement of Bathyphytophilus (with Aenigmabonus) in a distinct family, Bathyphytophilidae Moskalev, 1978.
    [Show full text]
  • Enzymatic Degradation of Organophosphorus Pesticides and Nerve Agents by EC: 3.1.8.2
    catalysts Review Enzymatic Degradation of Organophosphorus Pesticides and Nerve Agents by EC: 3.1.8.2 Marek Matula 1, Tomas Kucera 1 , Ondrej Soukup 1,2 and Jaroslav Pejchal 1,* 1 Department of Toxicology and Military Pharmacy, Faculty of Military Health Sciences, University of Defence, Trebesska 1575, 500 01 Hradec Kralove, Czech Republic; [email protected] (M.M.); [email protected] (T.K.); [email protected] (O.S.) 2 Biomedical Research Center, University Hospital Hradec Kralove, Sokolovska 581, 500 05 Hradec Kralove, Czech Republic * Correspondence: [email protected] Received: 26 October 2020; Accepted: 20 November 2020; Published: 24 November 2020 Abstract: The organophosphorus substances, including pesticides and nerve agents (NAs), represent highly toxic compounds. Standard decontamination procedures place a heavy burden on the environment. Given their continued utilization or existence, considerable efforts are being made to develop environmentally friendly methods of decontamination and medical countermeasures against their intoxication. Enzymes can offer both environmental and medical applications. One of the most promising enzymes cleaving organophosphorus compounds is the enzyme with enzyme commission number (EC): 3.1.8.2, called diisopropyl fluorophosphatase (DFPase) or organophosphorus acid anhydrolase from Loligo Vulgaris or Alteromonas sp. JD6.5, respectively. Structure, mechanisms of action and substrate profiles are described for both enzymes. Wild-type (WT) enzymes have a catalytic activity against organophosphorus compounds, including G-type nerve agents. Their stereochemical preference aims their activity towards less toxic enantiomers of the chiral phosphorus center found in most chemical warfare agents. Site-direct mutagenesis has systematically improved the active site of the enzyme. These efforts have resulted in the improvement of catalytic activity and have led to the identification of variants that are more effective at detoxifying both G-type and V-type nerve agents.
    [Show full text]
  • Flip Your Lid for Squid!
    FLIP YOUR LID FOR SQUID! Adapted from http://njseagrant.org/wp-content/uploads/2014/03/squid_dissection.pdf PURPOSE Students learn the basics of squid anatomy and physiology by conducting a squid dissection. MATERIALS • frozen whole squid—not “clean” and not cut (get whole squid in frozen section of the grocery store) • hand lenses • dissection pan (plate) • scissors • tweezers • probe or toothpick • paper towels PROCEDURE Dissection of External Anatomy • Have students observe their squids for a few moments looking at the relationship between head and the rest of the body. Then ask students why they think squid are in the family of cephalopods (head-foots). • Tentacles and Arms: Have students count the number of arms. They may use the toothpicks to spread out the squid arms. Ask if all the arms look the same? There should be eight short arms and 2 long arms. Explain that the long thin arms with suckers only at the ends are called tentacles. The tentacles large ends with suckers are known as clubs. The tentacles are used to strike out and capture prey. The eight arms are used to hold onto prey when captured and bring food into its mouth. • Suction Cups: Student may use the magnifying lenses to get a closer look at the suction cups on each arm and tentacles. The suction cups have a small-toothed ring around each one and they are on short stalks. The suction cups are like suckers that help the arms hold onto the prey when it is captured and tries to escape. • Beak and Buccal Mass: Located within the circle of arms students can locate the squids mouth which is a beak.
    [Show full text]
  • Littorina Littorea
    Zarai et al. Lipids in Health and Disease 2011, 10:219 http://www.lipidworld.com/content/10/1/219 RESEARCH Open Access Immunohistochemical localization of hepatopancreatic phospholipase in gastropods mollusc, Littorina littorea and Buccinum undatum digestive cells Zied Zarai1, Nicholas Boulais2, Pascale Marcorelles3, Eric Gobin3, Sofiane Bezzine1, Hafedh Mejdoub1 and Youssef Gargouri1* Abstract Background: Among the digestive enzymes, phospholipase A2 (PLA2) hydrolyzes the essential dietary phospholipids in marine fish and shellfish. However, we know little about the organs that produce PLA2, and the ontogeny of the PLA2-cells. Accordingly, accurate localization of PLA2 in marine snails might afford a better understanding permitting the control of the quality and composition of diets and the mode of digestion of lipid food. Results: We have previously producted an antiserum reacting specifically with mSDPLA2. It labeled zymogen granules of the hepatopancreatic acinar cells and the secretory materials of certain epithelial cells in the depths of epithelial crypts in the hepatopancreas of snail. To confirm this localization a laser capture microdissection was performed targeting stained cells of hepatopancreas tissue sections. A Western blot analysis revealed a strong signal at the expected size (30 kDa), probably corresponding to the PLA2. Conclusions: The present results support the presence of two hepatopancreatic intracellular and extracellular PLA2 in the prosobranchs gastropods molluscs, Littorina littorea and Buccinum undatum and bring insights on their localizations. Keywords: phospholipase A2, digestive enzyme, littorina littorea, Buccinum undatum hepatopancreas, immunolocalisation Background in littoral dwellers Littorina, the activity of which Snails require lipids for metabolic energy and for main- depends on the tide level. The presence of massive shell taining the structure and integrity of cell membranes in enhances demands in energy needed for supporting common with other animals to tolerate environemental movement and activity.
    [Show full text]
  • Structure and Function of the Digestive System in Molluscs
    Cell and Tissue Research (2019) 377:475–503 https://doi.org/10.1007/s00441-019-03085-9 REVIEW Structure and function of the digestive system in molluscs Alexandre Lobo-da-Cunha1,2 Received: 21 February 2019 /Accepted: 26 July 2019 /Published online: 2 September 2019 # Springer-Verlag GmbH Germany, part of Springer Nature 2019 Abstract The phylum Mollusca is one of the largest and more diversified among metazoan phyla, comprising many thousand species living in ocean, freshwater and terrestrial ecosystems. Mollusc-feeding biology is highly diverse, including omnivorous grazers, herbivores, carnivorous scavengers and predators, and even some parasitic species. Consequently, their digestive system presents many adaptive variations. The digestive tract starting in the mouth consists of the buccal cavity, oesophagus, stomach and intestine ending in the anus. Several types of glands are associated, namely, oral and salivary glands, oesophageal glands, digestive gland and, in some cases, anal glands. The digestive gland is the largest and more important for digestion and nutrient absorption. The digestive system of each of the eight extant molluscan classes is reviewed, highlighting the most recent data available on histological, ultrastructural and functional aspects of tissues and cells involved in nutrient absorption, intracellular and extracellular digestion, with emphasis on glandular tissues. Keywords Digestive tract . Digestive gland . Salivary glands . Mollusca . Ultrastructure Introduction and visceral mass. The visceral mass is dorsally covered by the mantle tissues that frequently extend outwards to create a The phylum Mollusca is considered the second largest among flap around the body forming a space in between known as metazoans, surpassed only by the arthropods in a number of pallial or mantle cavity.
    [Show full text]