Sperm ultrastructure in Hemidonax pictus (Hemidonacidae, Bivalvia, Mollusca): comparison with other heterodonts, especially Cardiidae, Donacidae and Crassatelloidea

The systematic position and affinities of the marine bivalve genus Hemidonax (Heterodonta, Veneroida) are investigated using comparative sperm ultrastructure, with particular focus on the various groups to which this genus has been assigned [Donacidae (Tellinoidea), Cardiidae (Cardioidea) and Crassatellidae (Crassatelloidea)]. Ultrastructural examination (using transmission electron microscopy) reveals that Hemidonax pictus produces sperm of the aquasperm type, with a short, rounded-conical acrosomal vesicle, a short, barrel-shaped nucleus, a short midpiece (composed of two centrioles and four surrounding mitochondria) and a flagellum containing a conventional 9 + 2 pattern axoneme. The acrosomal vesicle exhibits a wedge-shaped, highly electron-dense, basal ring component, and less dense anterior component (including a thin, electron-lucent layer apically, which may prove to be a useful apomorphy for Hemidonax ). A loose, granular deposit of subacrosomal material is located within a narrow invagination traversing most of the length of the vesicle. Comparison with sperm of other heterodont bivalves shows no close connection between Hemidonax and the Donacidae (Tellinoidea) or with the Crassatellidae (or other crassatelloideans). Although certain Veneridae (Veneroidea) and Cardiidae (Cardioidea, especially Fragum ) show much better conformity in sperm morphology to that observed in Hemidonax , no complete match could be found among studied taxa. We conclude that Hemidonax should be retained in its own, previously introduced family Hemidonacidae, and the latter be placed incertae sedis within the Euheterodonta.  © 2008 The Linnean Society of London, Zoological Journal of the Linnean Society , 2008, 153 , 325–347.     

Bivalvia – a look at the Branches

Systematic research on bivalved molluscs (Mollusca: Bivalvia = Pelecypoda) is briefly reviewed in an introduction to a series of papers focusing on seven of the larger branches of the bivalve tree. These are presented in an attempt to summarize current knowledge, to stimulate new research and to highlight needs for future research focus. A revised classification of extant bivalve families (with synonyms and included subfamilies) is presented, based on information compiled from the latest palaeontological, morphological and molecular data.  © 2006 The Linnean Society of London, Zoological Journal of the Linnean Society , 2006, 148 , 223–235.     

Sanitation with sponge and plunger: western Atlantic slit-wormsnails (Mollusca: Caenogastropoda: Siliquariidae)

Siliquariid Tenagodus (synonym: Siliquaria) snails are obligatory sponge commensals, with uncoiling and laterally slitted shells embedded inside Demospongiae hosts, and shell apertures facing the outside allowing for respiratory and gill‐filter‐feeding activities. Live‐collected animals observed in situ within hosts provide the first detailed functional morphological study of the group, and form the basis for systematic revision of the western Atlantic members of type genus Tenagodus (Siliquariidae, synonym: Tenagodidae). Three species are recognized. Overall anatomical features of wide‐ranging Atlantic T. modestus (Dall, 1881) and T. squamatus (de Blainville, 1827) [ = T. anguillae Mörch, 1861] are similar to those previously described for New Zealand Pyxipoma. A third species, Tenagodus barbadensis sp. nov. , is described from Barbados, based on shell characters. The three species live embedded in a few species of halichondriid and thrombid sponges at depths ranging from c. 20 to several hundred metres and show several characters not previously documented for the family. These include a short compressed‐S‐shaped osphradium, an anal opening positioned in the posterior mantle cavity, and cuspidate inner marginal radular teeth. Presence of shell septa sealing earlier parts of the shell, first described in the early 1800s but subsequently disputed, was verified. Observations on living T. squamatus demonstrated the use of the large tight‐fitting operculum in plunger‐like fashion, flushing the mantle cavity and discharging waste material (including faeces from the posteriorly located anus) through the shell slit into the host sponge's aquiferous canal system. Uncoiling shells, shell and mantle slits, and specialized opercular, gill and gut morphology are interpreted as adaptive traits of the sessile mode of life embedded in sponge tissue. Actively maintained linkage between snail and sponge water‐flow systems provides mutual benefits; these include the allowance for rapid defensive withdrawal and return‐to‐feeding position of the snail (by using the sponge canal system as a vent or reservoir for displaced water), sanitation of the mantle cavity (waste material can leave the snail through the shell slit at the posterior end of the mantle cavity, avoiding fouling of the gill‐feeding system), and by providing increased water flow and, potentially, extra nutritional particles for the sponge (food and waste particles stemming from the snail's activity). The lectotypes selected herein are Serpula anguina Linnaeus, 1758, Tenagodus anguillae Mörch, 1861, and Siliquaria modesta Dall, 1881. © 2004 The Linnean Society of London, Zoological Journal of the Linnean Society, 2004, 140 , 307–333.     

REPRODUCTIVE BIOLOGY OF THE SESSILE GASTROPOD VERMICULARIA SPIRATA (CERITHIOIDEA: TURRITELLIDAE)

The reproductive and developmental biology of the sessile gastropodVermicularia spirata (Philippi, 1836), collected from the FloridaKeys, was studied from living and preserved material. Individualsof this species attach themselves to a variety of substrata,but were mainly found embedded in the white sponge Geodia gibberosa.Pallial reproductive structures of both sexes of V. spiratawere found greatly to resemble those of Turritella communis,a free-living member of the same family. In both species, animalsof both sexes have open pallial ducts formed by two wide, recurvedlaminae. In the female of V. spirata, the laminae of the pallialoviduct serve as a capsule gland; a pair of side pockets representa fertilization pouch (possibly doubling as a copulatory bursa)and a seminal receptacle. The functional significance of theextensive, open, pallial sperm duct is not yet clear. Vermiculariaspirata is a protandrous hermaphrodite, and small males arefree-living; they become attached at about the time they undergosex reversal. Fertilization is probably brought about by malescrawling close to the apertures of the large, sessile femalesbefore releasing sperm. Egg capsules are brooded in the females'mantle cavities. Ova of about 300 µm diameter give riseto large (about 600 µm long) swimming-crawling veligerlarvae with shells of two and a half whorls. The veligers arecapable of metamorphosis at the time of hatching, but siblingsfrom one brood metamorphosed over a two-week period in the laboratory.Juvenile snails grew rapidly by filtering phytoplankton addedto their culture water. The life history of V. spirata is welladapted to assure fertilization and recruitment in a speciesotherwise committed to a sessile, filter-feeding existence. (Received 3 February 1989; accepted 19 April 1989)     

Phylogeny of Veneroidea (Mollusca: Bivalvia) based on morphology and molecules

The largest Recent family of Bivalvia, the marine Veneridae with approximately 800 species, comprises one of the least understood and most poorly defined molluscan taxa, despite including some of the most economically important and abundant bivalves, for example quahog, Pismo clams, and Manila clams. A review of previous phylogenetic analyses including the superfamily Veneroidea (Veneridae, Petricolidae, Glauconomidae, Turtoniidae, Neoleptonidae) and within the Veneridae shows minimal taxon sampling leading to weak conclusions and few supported synapomorphies. New phylogenetic analyses on 114 taxa tested the monophyly of Veneroidea, Veneridae, and 17 nominal venerid subfamilies, using morphological (conchological, anatomical) data and molecular sequences from mitochondrial (16S, cytochrome oxidase I) and nuclear (28S, histone 3) genes. Morphological analyses using 45 exemplar taxa and 23 traditional characters were highly homoplastic and failed to reconstruct traditional veneroid classification. Full morphological analyses (31 characters) supported the monophyly of Veneroidea and Veneridae but only when certain taxa were excluded, revealing analytical difficulties caused by a suite of characters associated with neotenous or miniaturized morphology. Molecular analyses resulted in substantially higher clade consistency. The combined molecular data set resulted in significant support for a particular topology. The monophyly of Veneridae was supported only when Petricolidae and Turtoniidae were subsumed, and recognized as members with derived or neotenous morphologies, respectively. Morphological character mapping on molecular trees retained a high level of homoplasy, but revealed synapomorphies for major branch points and supported six subfamily groups (Dosiniinae, Gemminae, Samarangiinae, Sunettinae, Tapetinae, combined Chioninae + Venerinae). Glauconomidae and Neoleptonidae are provisionally maintained in Veneroidea pending further study; Petricolinae and Turtoniinae are placed in Veneridae. © 2006 The Linnean Society of London, Zoological Journal of the Linnean Society, 2006, 148 , 439–521.