Thecal designs in isorophinid edrioasteroids

A study of functional morphology in the edrioasteroid suborder Isorophina reveals three major thecal designs: domal, pyrgate, and clavate. Pyrgate forms are characterized by specialized morphologic features that facilitate extension of the theca well above the substrate and contraction of the theca to a low, streamlined, domal profile. Domal forms have a low, domal thecal profile capable of little shape change. Clavate forms are characterized by modifications to the pyrgate theca to facilitate higher-level suspension feeding. Pyrgate species are generalized edrioasteroids that inhabited a variety of nearshore open-marine environments. Domal species are small specialized edrioasteroids that inhabited shallow-marine to intertidal environments. Clavate species inhabited offshore, open-marine environments. The size reduction of the peripheral rim and the modifications to the pedunculate zone are adaptations allowing clavate edrioasteroids to compete for small attachment sites while maintaining the ability to extend the theca for higher-level suspension feeding and respiration. A phylogenetic analysis of well-known isorophinid edrioasteroids to determine the relationships between the three designs indicates that domal species are a monophyletic group within the Isorophinidae, clavate species are a monophyletic group within the Agelacrinitidae, and isorophinid pyrgate species are a paraphyletic group ancestral to both domal and clavate forms. □ Edrioasteroidea, Echinodermata, functional morphology, phylogeny.     

FINE STRUCTURE OF THE IMMOBILE DINOCOCCALEAN CYSTODINIUM BATAVIENSE (DINOPHYCEAE)1

The fine structure of the immobile stage of C. bataviense Klebs reveals several features which may prove helpful in understanding the parameters of the order Phytodinales. The cell covering is confluent with no thecal plates. Neither external membranes nor pores are present. The pusule tubules and collecting chamber have no external opening via flagellar pores or canals. The cell is highly vacuolate with a tonoplast-like membrane delimiting the pusule system from the cytoplasm in the interior of the cell. Polyvesicular bodies, mitochondria with enlarged matrices containing electron-dense bodies, vesicles which may contain flagellar hairs, crystals, and large accumulation bodies are present.     

A reappraisal of the paradigm method of functional analysis in fossils

The paradigm method involves comparing fossil organs with theoretical structures (paradigms) which are 100% efficient in performing proposed functions. Applications of the method have been criticised as being unsystematic and mechanistic, producing conflicting results and ignoring pertinent limitations. Selected interpretations of zigzag slits and spines in brachiopods and bivalve molluscs are re-examined. None invalidate the method. The last step in paradigm analysis, i.e. selecting the most appropriate function, is a major weakness and should be avoided. Repeated paradigm analysis may be used to interpret evolutionary trends in terms of adaptation and functional efficiency.     

The α1-adrenergic receptors: diversity of signaling networks and regulation

The α(1)-adrenergic receptor (AR) subtypes (α(1a), α(1b), and α(1d)) mediate several physiological effects of epinephrine and norepinephrine. Despite several studies in recombinant systems and insight from genetically modified mice, our understanding of the physiological relevance and specificity of the α(1)-AR subtypes is still limited. Constitutive activity and receptor oligomerization have emerged as potential features regulating receptor function. Another recent paradigm is that β arrestins and G protein-coupled receptors themselves can act as scaffolds binding a variety of proteins and this can result in growing complexity of the receptor-mediated cellular effects. The aim of this review is to summarize our current knowledge on some recently identified functional paradigms and signaling networks that might help to elucidate the functional diversity of the α(1)-AR subtypes in various organs.     

The α1-adrenergic receptors: diversity of signaling networks and regulation

The α₁-adrenergic receptor (AR) subtypes (α_1a, α_1b, and α_1d) mediate several physiological effects of epinephrine and norepinephrine. Despite several studies in recombinant systems and insight from genetically modified mice, our understanding of the physiological relevance and specificity of the α₁-AR subtypes is still limited. Constitutive activity and receptor oligomerization have emerged as potential features regulating receptor function. Another recent paradigm is that βarrestins and G protein-coupled receptors themselves can act as scaffolds binding a variety of proteins and this can result in growing complexity of the receptor-mediated cellular effects. The aim of this review is to summarize our current knowledge on some recently identified functional paradigms and signaling networks that might help to elucidate the functional diversity of the α₁-AR subtypes in various organs.     

Pollen Organ Telangiopsis sp. of Late Devonian Seed Plant and Associated Vegetative Frond

Pollen organ Telangiopsis sp., associated with but not attached to vegetative fronds, has been collected from the Upper Devonian (Famennian) Wutong Formation, Dongzhi County, Anhui Province, China. Fertile axes with terminal pollen organs are dichotomous for 2–4 times and may be proximally attached by fragmentary pinnules. Pollen organs are synangiate and borne on the top of a short stalk. Synangia are radial in symmetry and each consists of 4–8 elongate microsporangia fused at base. Microsporangia have a longitudinal dehiscence line and show a tapered apex. The associated stem is spiny and bears a vegetative frond which bifurcates once at the basalmost part. Frond rachises possess one order of pinna arranged alternately. Pinnules are borne alternately, planate, highly dissected, and equally dichotomous for 2–3 times. Comparisons among Late Devonian seed plants recognize several branching patterns in the fertile fronds/axes bearing terminal pollen organs. Telangiopsis sp. reinforces that the Late Devonian pollen organs are synangiate usually with basally fused microsporangia. It is suggested that the evolutionary divergence of radial and bilateral symmetries of pollen organs may have occurred in the Famennian, when the earliest seed plants evolved planate and sometimes laminate pinnules.     

Cellular analysis of appetitive learning in invertebrates

In recent years significant progress has been made in the analysis of the cellular mechanisms underlying appetitive learning in two invertebrate species, the pond snail Lymnaea stagnalis and the honeybee Apis mellifera. In Lymnaea, both chemical (taste) and tactile appetitive conditioning paradigms were used and cellular traces of behavioural classical conditioning were recorded at several specific sites in the nervous system. These sites included sensory pathways, central pattern generator and modulatory interneurones as well as motoneurones of the feeding network. In the honeybee, a chemical (odour) appetitive conditioning paradigm resulted in cellular changes at different sites in the nervous system. In both the pond snail and the honeybee the activation of identified modulatory interneurones could substitute for the use of the chemical unconditioned stimulus, making these paradigms even more amenable to more detailed cellular and molecular analysis.     

Mississippian crinoid biodiversity,biogeography and macroevolution

Abstract: The biodiversity and biogeography of 217 genera of Mississippian crinoids from North America and the British Isles shed light on the macroevolutionary turnover between the Middle Palaeozoic and Late Palaeozoic Crinoid Evolutionary Faunas. This turnover resulted from steady differential extinction among clades during the middle Mississippian after crinoids reached their Phanerozoic peak of generic richness during the early Mississippian. This peak richness was primarily a function of Mississippian originations rather than Devonian–holdover taxa. North America had 100 per cent higher generic richness than the British Isles, but rarefaction analysis adjusts the difference to only 37 per cent higher. Rarefaction demonstrated that North America had increased biodiversity, compared to the British Isles, almost entirely among monobathrid camerates, disparids and primitive cladids. In contrast, diplobathrid camerates, advanced cladids and flexibles had the same generic biodiversity between regions, when compared using rarefaction. The early Mississippian radiation resulted from two primary causes: (1) the expansion of Tournaisian carbonate ramps following the Frasnian mass extinction of reef faunas and (2) the predatory release in the Tournaisian following the end‐Famennian Hangenberg extinction of durophagous fishes. A majority of crinoid genera from the British Isles are cosmopolitan. When combined with rarefaction analysis and evidence for more first occurrences in North America, this suggests higher origination rates in North America, especially when carbonate ramps were widespread. With the gradual reduction in the area of carbonate ramps from the early to late Mississippian, in conjunction with the radiation of new durophagous fishes, camerate crinoids in particular experienced continuous background extinction, without replacement, beginning during the earliest Viséan (late Osagean). By middle Viséan time (late Meramecian) advanced cladids were dominant in all settings. This resulted in the transition from the Middle Palaeozoic to the Late Palaeozoic Crinoid Macroevolutionary Fauna.     

New Pennsylvanian (Moscovian) echinoderms from Xinjiang Uyghur Autonomous Region,western China

The few Pennsylvanian echinoderm faunas reported from the Paleotethys are from China, Japan, and Australia. The Japanese and Chinese faunas contain camerates that are rare in Pennsylvanian faunas worldwide.Genera of one monobathrid camerate, two disparids, five cladids, one flexible, one blastoid, and one archaeocidarid are reported from the late Moscovian uppermost part of the Qijiagou Formation or lowermost part of the Aoertu Formation in the Taoshigo Valley near Taoshuyuan Village, Xinjiang Uyghur Autonomous Region, China. They are here referred to as the Aoertu fauna, which is most closely allied with Pennsylvanian crinoids reported from a slightly older fauna from the Qijiagou Formation in the Taoshigo Valley and with faunas known from Japan and North America. Most taxa are identified to the genus level and left in open nomenclature because of poor or partial preservation. In addition, camerate ossicles and a cup of Synbathocrinus are reported from the early Moscovian part of the Sanquanzi Formation at Yamansu, southeast of the Taoshigo Valley. New taxa described are: Synbathocrinus labrus n. sp., Stellarocrinus qijiagouensis n. sp. and Metaperimestocrinus aoertuensis n. sp.     

Ultrastructural investigation of the nuchal organs ofPygospio elegans (Polychaeta). I. Larval nuchal organs

The structural differentiation of the nuchal organs during the post-embryonic development ofPygospio elegans is described. The sensory organs are composed of two cell types: ciliated cells and bipolar primary sensory cells, constituting the nuchal ganglion, which is associated with both the sensory epithelium and the brain. Since the sensory neurons are largely integrated into posterolateral parts of the cerebral ganglion, the nuchal organs are primary presegmental structures. The microvilli of the ciliated cells form a cover over the cuticle with a presumed protective function. An extracellular space extends between cuticle and sensory epithelium. The distal dendrites of the sensory cells terminate in sensory bulbs, bearing one modified sensory cilium each that projects into the olfactory chamber, embedded within the secretion of the ciliated cells. During development, the nuchal organs increase in size. This is accompanied by a shift in position, an expansion of the sensory area, and secretory activity of the ciliated cells. The nuchal ganglion differentiates into three nuchal centres forming three distinct sensory areas around the ciliated region. Each nuchal complex reveals two short nuchal nerves comprising the sensory axons, which enter the posterior circumesophageal connective. The sensory cells lying in the brain exhibit neurosecretory activity; the sensory cilia enlarge their surface area by dilating and branching. Nuchal organs accomplish the basic structural adaptions of chemoreceptors and show structural analogies to arthropod olfactory sensilla; thus, there is every reason to suppose chemoreceptor function.     

The Morphology of the Lorenzinian Ampullae of the Sturgeon Acipenser ruthenus (Pisces: Chondrostei)

Jørgensen, J. M. 1980. The morphology of the Lorenzinian ampullae of the sturgeon Acipenser ruthenus (Pisces: Chondrostei). (Zoological Laboratory, University of Aarhus, Denmark.) — Acta zool. (Stockh.) 61 (2): 87–92. The snout of a sturgeon, Acipenser ruthenus (Chondrostei, Osteichthyes) is provided with sensory pores. Light and electron microscopical examination of these reveals that the ampullary organs have a sensory epithelium very similar to what has been found in the Lorenzinian ampullae, which are electroreceptors previously examined at a fine structural level in elasmobranchs and the paddle-fish, Polyodon spathula. The sensory cells are pear-shaped with a very small apical part, in the centre of which there is a short cilium. Basally, the sensory cells make several contacts with button-shaped nerve-endings. The presumed synaptic area in the sensory cell is characterized by a presynaptic sheet surrounded by vesicles. Only one type of nerve ending, an afferent type, has been observed.     

Foreword

The morphology of abdominal and alar androconial organs of four species representing four genera of danaine butterflies is described in detail, based mainly on scanning electron microscopy. The findings are discussed with respect to functional significance and phyletic development of the organs.     

Androconial systems in Danainae (Lepidoptera): functional morphology of Amauris, Danaus, Tirumala and Euploea

The morphology of abdominal and alar androconial organs of four species representing four genera of danaine butterflies is described in detail, based mainly on scanning electron microscopy. The findings are discussed with respect to functional significance and phyletic development of the organs.     

Identification and activity-dependent labeling of peripheral sensory structures on a spionid polychaete

In marine sedimentary habitats, chemoreception is thought to coordinate feeding in many deposit-feeding invertebrates such as polychaetes, snails, and clams. Relatively little is known, however, about the chemosensory structures and mechanism of signal transduction in deposit feeders. Using electron microscopy, confocal laser scanning microscopy (CLSM), and immunohistochemistry, we investigated the structure and function of putative chemosensory cells on the feeding appendages of a deposit-feeding polychaete species, Dipolydora quadrilobata. Tufts of putative sensory cilia were distributed over the prostomium and feeding palps and typically occurred next to pores. Examination of these regions with transmission electron microscopy revealed multiciliated cells with adjacent glandular cells beneath the pores. The sensory cells of prostomium and palps were similar, displaying an abundance of apical mitochondria and relatively short ciliary rootlets. Staining with antiserum against acetylated alpha-tubulin was examined by CLSM, and revealed axonal processes from putative sensory tufts on the palp surface to palp nerves, as well as many free nerve endings. Activity-dependent cell labeling experiments were used to test the sensitivity of putative sensory cells on the palps to an amino acid mixture that elicited feeding in previous behavioral experiments. In static exposures, the number of lateral and abfrontal cells labeled in response to the amino acid mixture was significantly greater than in the controls. Ultrastructural, positional, and now physiological evidence strongly suggests that spionid feeding palps are equipped with sensory cells, at least some of which function as chemoreceptors.     

The callistophytales (Pteridospermopsida): Reproductively sophisticated paleozoic gymnosperms

The Callistophytales nov. order is proposed for a small family of Pennsylvanian and possibly Permian pteridosperms. Plants conform to two species of Callistophyton and their reproductive organs. The small, eustelic sporophytes have a scrambling, shrub-like habit, profuse branching, adventitious roots and pinnately compound fern-like leaves with sphenopterid pinnules. Reproductive organs are borne on the abaxial surface of the pinnules, and consist of cardiocarpalean ovules and synangiate pollen organs with saccate pollen. Gametophyte development and reproductive biology conform closely to those of extant gymnosperms in the Coniferales. Anatomically preserved reproductive organs of the major groups of Paleozoic gymnosperms are compared, and a closer than currently recognized relationship of Paleozoic seed plants is proposed.     

Before the extinction – Permian platyceratid gastropods attached to platycrinitid crinoids and an abnormal four-rayed Platycrinites s.s. wachsmuthi (Wanner) from West Timor

The occurrence of Paleozoic gastropods attached to echinoderms has been recognized for nearly 170 years. Specimens have been illustrated from each of the geologic periods from the Ordovician to Permian. We illustrate two occurrences of Permian platycrinitid camerate crinoids from West Timor, Platycrinites s.s. wachsmuthi (Wanner) and Neoplatycrinus dilatatus Wanner, that have the platyceratid attached on the tegmen on the former and along the radial summit on the latter. Both platyceratids barely cover the anal opening and suppress the development of the arms of at least one ray. The D ray arms are suppressed on Platycrinites s.s. wachsmuthi, whereas the development of the C ray arms and perhaps the most adjacent arms of the D and B rays are suppressed on Neoplatycrinus dilatatus. An additional specimen of Neoplatycrinus major retains the impressed conch outline of a formerly attached platyceratid on the tegmen. This is the first report of a platyceratid/Neoplatycrinus association. The West Timor occurrences are among the youngest known of the platyceratid/platycrinitid association before the End-Permian extinction of the camerates. In addition, an abnormal four-rayed theca of Platycrinites s.s. wachsmuthi is described.     

Developmental constraint of insect audition

Background

Insect ears contain very different numbers of sensory cells, from only one sensory cell in some moths to thousands of sensory cells, e.g. in cicadas. These differences still await functional explanation and especially the large numbers in cicadas remain puzzling. Insects of the different orders have distinct developmental sequences for the generation of auditory organs. These sensory cells might have different functions depending on the developmental stages. Here we propose that constraints arising during development are also important for the design of insect ears and might influence cell numbers of the adults.

Presentation of the hypothesis

We propose that the functional requirements of the subadult stages determine the adult complement of sensory units in the auditory system of cicadas. The hypothetical larval sensory organ should function as a vibration receiver, representing a functional caenogenesis.

Testing the hypothesis

Experiments at different levels have to be designed to test the hypothesis. Firstly, the neuroanatomy of the larval sense organ should be analyzed to detail. Secondly, the function should be unraveled neurophysiologically and behaviorally. Thirdly, the persistence of the sensory cells and the rebuilding of the sensory organ to the adult should be investigated.

Implications of the hypothesis

Usually, the evolution of insect ears is viewed with respect to physiological and neuronal mechanisms of sound perception. This view should be extended to the development of sense organs. Functional requirements during postembryonic development may act as constraints for the evolution of adult organs, as exemplified with the auditory system of cicadas.     

How tetrapods feed in water: a functional analysis by paradigm

Mechanical theory is used to erect a paradigm predicting the manipulations used by carnivorous aquatic amphibians, reptiles, birds and mammals to catch, subdue, process and swallow their prey. These predictions are confirmed by observational evidence. Most aquatic predatory tetrapods use long, prehensile tooth-armed jaws as pincer jaws to snap shut onto the prey and catch and kill it, although some use the flexibility of long necks in spear fishing and some odontocetes may stun prey with sonar. Most do not have cutting or nipping dentitions as these cannot be used on prey which is freely floating. They use caniniform dentition to hold and kill prey, or in some cases crushing dentition to break open hard-shelled prey. They dismember prey by dynamic loading, snatching bites so quickly that the prey tears. They use shake feeding, shaking the prey apart from side to side above the water. If the prey is too large to lift above the water they use twist feeding, twisting pieces off. Small pieces are easily swallowed but larger pieces are held above the water and swallowed by tilting the head back in gravity feeding, or by jerking the head back and forth in incrtial feeding. Some animals use mobile jaws to pull prey back into the mouth in ratchet feeding. Filter feeding evades these problems by feeding on very small prey. The use of paradigms in functional analysis is discussed with special reference to this work. The paradigm method is shown to be the most suitable one. There has been repeated convergent and parallel evolution of adaptations to feed in water.     

Ambulacral growth allometry in edrioasteroids: functional surface‐volume change in ontogeny and phylogeny

McKinney, M. L. & Sumrall, C. D. 2010: Ambulacral growth allometry in edrioasteroids: functional surface‐volume change in ontogeny and phylogeny. Lethaia, Vol. 44, pp. 102–108. Most organisms do not maintain geometric similarity as they grow, in large part because of surface‐volume interactions. Because respiratory and food‐acquiring organs are dependent on surface area, which increases more slowly than volume, organisms have evolved many strategies to increase the efficiency of, and/or the functional surface areas of these organs. Here, we report some preliminary results comparing area of the feeding apparatus (ambulacra) versus the volume of the theca for a suite of isorophid edrioasteroid species at various ontogenetic sizes. Regression of log (ambulacral area) on log (thecal volume) indicates a strongly constrained allometric pattern whereby the ontogenies of all measured species fall on or near the same line (r² = 0.962, n = 55), with a slope (k) = 0.654 (± 0.018). This slope and associated 0.05 standard error (0.618–0.690) is within the bounds of that expected from increasing surface area to keep pace with the metabolic demands of increasing thecal size. This allometric value is also comparable to the size scaling of metabolism and respiratory and feeding surfaces in many living and a few fossil invertebrates (k ～ 0.5–0.9). The edrioasteroid species analysed show a very wide variety of changes in ambulacral length, width and sinuosity, documenting many different patterns for achieving the same goal of increasing surface area to keep pace with volume increase. There is no evidence of increasing feeding efficiency. □Edrioasteroid, allometry, ambulacrum, surface‐volume, echinoderm.