Your search keyword '"Sepia anatomy & histology"' showing total 28 results

1. Biological light-weight materials: The endoskeletons of cephalopod mollusks.

Author

Griesshaber E, Checa AG, Salas C, Hoffmann R, Yin X, Neuser R, Rupp U, and Schmahl WW

Subjects

Animals, Mollusca, Decapodiformes, Cephalopoda, Sepia anatomy & histology

Abstract

Structural biological hard tissues fulfill diverse tasks: protection, defence, locomotion, structural support, reinforcement, buoyancy. The cephalopod mollusk Spirula spirula has a planspiral, endogastrically coiled, chambered, endoskeleton consisting of the main elements: shell-wall, septum, adapical-ridge, siphuncular-tube. The cephalopod mollusk Sepia officinalis has an oval, flattened, layered-cellular endoskeleton, formed of the main elements: dorsal-shield, wall/pillar, septum, siphuncular-zone. Both endoskeletons are light-weight buoyancy devices that enable transit through marine environments: vertical (S. spirula), horizontal (S. officinalis). Each skeletal element of the phragmocones has a specific morphology, component structure and organization. The conjunction of the different structural and compositional characteristics renders the evolved nature of the endoskeletons and facilitates for Spirula frequent migration from deep to shallow water and for Sepia coverage over large horizontal distances, without damage of the buoyancy device. Based on Electron-Backscatter-Diffraction (EBSD) measurements and TEM, FE-SEM, laser-confocal-microscopy imaging we highlight for each skeletal element of the endoskeleton its specific mineral/biopolymer hybrid nature and constituent arrangement. We demonstrate that a variety of crystal morphologies and biopolymer assemblies are needed for enabling the endoskeleton to act as a buoyancy device. We show that all organic components of the endoskeletons have the structure of cholesteric-liquid-crystals and indicate which feature of the skeletal element yields the necessary mechanical property to enable the endoskeleton to fulfill its function. We juxtapose structural, microstructural, texture characteristics and benefits of coiled and planar endoskeletons and discuss how morphometry tunes structural biomaterial function. Both mollusks use their endoskeleton for buoyancy regulation, live and move, however, in distinct marine environments., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023. Published by Elsevier Inc.)

Published

2023

2. Immunohistochemical Approach to Understanding the Organization of the Olfactory System in the Cuttlefish, Sepia officinalis.

Author

Scaros AT, Croll RP, and Baratte S

Subjects

Animals, Antibodies, Brain anatomy & histology, Brain metabolism, In Situ Hybridization, Microscopy, Fluorescence, Models, Animal, Neurotransmitter Agents metabolism, Olfactory Pathways growth & development, Olfactory Pathways metabolism, Olfactory Receptor Neurons metabolism, Sepia growth & development, Sepia metabolism, Smell physiology, Tissue Fixation, Immunohistochemistry methods, Olfactory Pathways anatomy & histology, Olfactory Receptor Neurons cytology, Sepia anatomy & histology

Abstract

Cephalopods are nontraditional but captivating models of invertebrate neurobiology, particularly in evolutionary comparisons. Cephalopod olfactory systems have striking similarities and fundamental differences with vertebrates, arthropods, and gastropods, raising questions about the ancestral origins of those systems. We describe here the organization and development of the olfactory system of the common cuttlefish, Sepia officinalis, using immunohistochemistry and in situ hybridization. FMRFamide and/or related peptides and histamine are putative neurotransmitters in olfactory sensory neurons. Other neurotransmitters, including serotonin and APGWamide within the olfactory and other brain lobes, suggest efferent control of olfactory input and/or roles in the processing of olfactory information. The distributions of neurotransmitters, along with staining patterns of phalloidin, anti-acetylated α-tubulin, and a synaptotagmin riboprobe, help to clarify the structure of the olfactory lobe. We discuss a key difference, the lack of identifiable olfactory glomeruli, in cuttlefish in comparison to other models, and suggest its implications for the evolution of olfaction.

Published

2018

3. Morphology of reproductive accessory glands in female Sepia pharaonis (Cephalopoda: Sepiidae) sheds light on egg encapsulation.

Author

Huang JD, Lee SY, Chiang TY, Lu CC, and Lee MF

Subjects

Animals, Epithelial Cells cytology, Female, Genitalia cytology, Genitalia ultrastructure, Sepia cytology, Sepia ultrastructure, Genitalia anatomy & histology, Ovum physiology, Sepia anatomy & histology

Abstract

The pharaoh cuttlefish, Sepia pharaonis, is an important cephalopod fishery species in southeastern Asia, with understudied reproductive physiology. The present study aimed to investigate the cellular characteristics of epithelial cells found in the nidamental glands (NGs) and accessory NGs (ANGs), as well as the structural connections between these two glands in mature female S. pharaonis. A histological analysis revealed two types of epithelial cells in NGs: Alcian blue-positive, PAS-negative mucosubstance-secreting cells and eosinophilic, PAS-positive granule-secreting cells. Using transmission electron microscopy, three types of epithelial cells were identified: cells with electron-dense granules, cells with electron-lucent granules, and cells with both cilia and microvilli in the apex. Mature ANGs contain an abundance of tubular units composed of epithelial cells resting on a thin layer of basal lamina. Innervated muscle cells are tightly adhered to the basal lamina. In addition, we observed epithelial canalization of ANG tubules penetrating through the connective tissue linking NGs and the walls of the tubules in ANGs, which allows the contents of the ANG tubules to be transported to the NGs. Our results suggest that ANGs participate in the encapsulation of the ova via the same pathway as NGs, which provides an important basis for future studies on the mechanism of protection provided by NGs and ANGs during embryonic development in S. pharaonis., (© 2018 Wiley Periodicals, Inc.)

Published

2018

4. White reflection from cuttlefish skin leucophores.

Author

Hanlon RT, Mäthger LM, Bell GRR, Kuzirian AM, and Senft SL

Subjects

Animal Communication, Animals, Color, Female, Light, Male, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Optical Phenomena, Skin Physiological Phenomena, Biological Mimicry physiology, Sepia anatomy & histology, Sepia physiology, Skin anatomy & histology, Skin Pigmentation physiology

Abstract

The highly diverse and changeable body patterns of cephalopods require the production of whiteness of varying degrees of brightness for their large repertoire of communication and camouflage behaviors. Leucophores are structural reflectors that produce whiteness in cephalopods; they are dermal aggregates of numerous leucocytes containing spherical leucosomes ranging in diameter from 200-2000 nm. In Sepia officinalis leucophores, leucocytes always occur in various combinations with iridocytes, cells containing plates that function as Bragg stacks to reflect light of particular wavelengths. Both spheres and plates contain the high-refractive-index protein reflectin. Four leucophore skin-patterning components were investigated morphologically and with spectrometry. In descending order of brightness they are: white fin spots, White zebra bands, White square, and White head bar. Different densities, thicknesses and proportions of leucocytes and iridocytes were correlated with the relative brightness measurements of the skin. That is, White fin spots and White zebra bands had leucocytes of the highest density, the greatest number of reflective cell layers, and the highest proportion of leucocytes to iridocytes. In contrast, the White square and White head bar had the lowest density of reflective cells, fewer cell layers and the lowest ratios of leucocytes to iridocytes. Leucophores are white in white light, yet reflect whatever colors are in the available light field: e.g. red in red light, green in green light, etc. Leucophores are physiologically passive, thus their ultrastructure alone is capable of diffusing all ambient wavelengths in all directions, regardless of the angle of incident light. However, the specific optical contributions of spherical leucosomes versus the associated plate-like iridosomes in producing whiteness versus brightness are yet to be determined. This study reveals complex morphological arrangements that produce white structural coloration for different brightnesses of skin by differentially combining spheres and plates.

Published

2018

5. Digestive enzyme ratios are good indicators of hatchling yolk reserve and digestive gland maturation in early life stages of cuttlefish Sepia officinalis L.: application of these new tools in ecology and aquaculture.

Author

Safi G, Martinez AS, Le Pabic C, Le Bihan E, Robin JP, and Koueta N

Subjects

Acid Phosphatase, Alkaline Phosphatase, Animals, Aquaculture, Cathepsins, Gastrointestinal Tract anatomy & histology, Sepia anatomy & histology, Trypsin, Gastrointestinal Tract physiology, Sepia physiology

Abstract

In Sepia officinalis (Linnaeus, 1758), the digestive gland matures during the first month post-hatching, while a shift from intracellular acid to extracellular alkaline digestion occurs. The purpose of this study was to investigate the possibility of using enzymatic ratios for the description of digestive system maturation in early life stages of S. officinalis. Second, it is intended to apply these new tools as eco-physiological indicators for understanding the impact of cuttlefish eggs' life history from different spawning sites of the English Channel on digestive performance of juveniles. An experimental rearing was performed over 35 days after hatching (DAH) on juveniles from wild collected eggs in 2010 and 2011. Four digestive enzyme activities and their ratios [i.e., trypsin, cathepsin, acid (ACP), and alkaline (ALP) phosphatase, ALP/ACP, and trypsin/cathepsin] were studied along with histological features (e.g., internal yolk surface and digestive gland development). The two enzyme ratios were good indicators of digestive system maturation allowing the study of the digestive gland's development. They were highly correlated to juveniles' weight increase and histological features of the gland in early DAH. These ratios described more accurately the shift occurring between the intracellular acid and the extracellular alkaline modes of digestion in S. officinalis and were more specific than separated enzyme activities. Their application as eco-physiological tools revealed that enzyme ratios reflected yolk content and digestive gland development in new hatching juveniles. Finally, ALP/ACP ratio was shown to be a powerful tool to describe growth performance of S. officinalis which is useful for aquaculture optimization.

Published

2018

6. First proteomic analyses of the dorsal and ventral parts of the Sepia officinalis cuttlebone.

Author

Le Pabic C, Marie A, Marie B, Percot A, Bonnaud-Ponticelli L, Lopez PJ, and Luquet G

Subjects

Animal Shells anatomy & histology, Animal Shells chemistry, Animals, Calcification, Physiologic, Proteins metabolism, Sepia anatomy & histology, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Spectroscopy, Fourier Transform Infrared, Animal Shells metabolism, Proteins analysis, Proteomics methods, Sepia metabolism

Abstract

Protein compounds constituting mollusk shells are known for their major roles in the biomineralization processes. These last years, a great diversity of shell proteins have been described in bivalves and gastropods allowing a better understanding of the calcification control by organic compounds and given promising applications in biotechnology. Here, we analyzed for the first time the organic matrix of the aragonitic Sepia officinalis shell, with an emphasis on protein composition of two different structures: the dorsal shield and the chambered part. Our results highlight an organic matrix mainly composed of polysaccharide, glycoprotein and protein compounds as previously described in other mollusk shells, with quantitative and qualitative differences between the dorsal shield and the chamber part. Proteomic analysis resulted in identification of only a few protein compounds underlining the lack of reference databases for Sepiidae. However, most of them contain domains previously characterized in matrix proteins of aragonitic shell-builder mollusks, suggesting ancient and conserved mechanisms of the aragonite biomineralization processes within mollusks., Biological Significance: The cuttlefish's inner shell, better known under the name "cuttlebone", is a complex mineral structure unique in mollusks and involved in tissue support and buoyancy regulation. Although it combines useful properties as high compressive strength, high porosity and high permeability, knowledge about organic compounds involved in its building remains limited. Moreover, several cuttlebone organic matrix studies reported data very different from each other or from other mollusk shells. Thus, this study provides 1) an overview of the organization of the main mineral structures found in the S. officinalis shell, 2) a reliable baseline about its organic composition, and 3) a first descriptive proteomic approach of organic matrices found in the two main parts of this shell. These data will contribute to the general knowledge about mollusk biomineralization as well as in the identification of protein compounds involved in the Sepiidae shell calcification., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published

2017

7. Turning performance in squid and cuttlefish: unique dual-mode, muscular hydrostatic systems.

Author

Jastrebsky RA, Bartol IK, and Krueger PS

Subjects

Animal Fins anatomy & histology, Animal Fins physiology, Animals, Biomechanical Phenomena, Body Size, Decapodiformes anatomy & histology, Sepia anatomy & histology, Swimming, Decapodiformes physiology, Sepia physiology

Abstract

Although steady swimming has received considerable attention in prior studies, unsteady swimming movements represent a larger portion of many aquatic animals' locomotive repertoire and have not been examined extensively. Squids and cuttlefishes are cephalopods with unique muscular hydrostat-driven, dual-mode propulsive systems involving paired fins and a pulsed jet. These animals exhibit a wide range of swimming behavior, but turning performance has not been examined quantitatively. Brief squid, Lolliguncula brevis, and dwarf cuttlefish, Sepia bandensis, were filmed during turns using high-speed cameras. Kinematic features were tracked, including the length-specific radius of the turn (R/L), a measure of maneuverability, and angular velocity (ω), a measure of agility. Both L. brevis and S. bandensis demonstrated high maneuverability, with (R/L)min values of 3.4×10(-3)±5.9×10(-4) and 1.2×10(-3)±4.7×10(-4) (mean±s.e.m.), respectively, which are the lowest measures of R/L reported for any aquatic taxa. Lolliguncula brevis exhibited higher agility than S. bandensis (ωa,max=725.8 versus 485.0 deg s(-1)), and both cephalopods have intermediate agility when compared with flexible-bodied and rigid-bodied nekton of similar size, reflecting their hybrid body architecture. In L. brevis, jet flows were the principal driver of angular velocity. Asymmetric fin motions played a reduced role, and arm wrapping increased turning performance to varying degrees depending on the species. This study indicates that coordination between the jet and fins is important for turning performance, with L. brevis achieving faster turns than S. bandensis and S. bandensis achieving tighter, more controlled turns than L. brevis., (© 2016. Published by The Company of Biologists Ltd.)

Published

2016

8. The functional-morphological adaptive strategy of digestive organs of decapodiform cephalopods.

Author

Omura A and Endo H

Subjects

Animals, Cecum anatomy & histology, Cecum physiology, Cephalopoda physiology, Decapodiformes anatomy & histology, Decapodiformes physiology, Digestive System Physiological Phenomena, Intestines anatomy & histology, Intestines physiology, Loligo anatomy & histology, Loligo physiology, Sepia anatomy & histology, Sepia physiology, Stomach anatomy & histology, Stomach physiology, Cephalopoda anatomy & histology, Digestive System anatomy & histology

Abstract

The digestive organs in decapodiform cephalopod species morphologically vary by individual lifestyle. We examined the following six species of adult decapodiformes cephalopods representing different habitats: Todarodes pacificus, Loligo bleekeri, Loligo edulis, Watasenia scintillans (pelagic), Sepia lycidas and Euprymna morsei (benthic). L. bleekeri and L. edulis possess a bursiform cecal sac connected to the cecum. Pelagic species have a single digestive gland smaller than in benthic species. T. pacificus has an oval digestive gland larger than that of L. bleekeri and L. edulis, which possess withered-looking and smaller digestive glands. In contrast, the digestive glands in benthic species are paired. S. lycidas and E. morsei have well-developed and larger digestive glands than those of the pelagic species. Well-developed digestive duct appendages are found in benthic species. In qualification of the mass of digestive organs, pelagic species have smaller stomachs, digestive glands and digestive ducts' appendages than benthic species. Because pelagic species need to swim, they may possess smaller stomachs and larger cecums for more rapid digestion. A smaller digestive gland may have the advantage of reducing the body weight in pelagic species for rapid swimming. In contrast, since benthic species require a longer time for digestion than pelagic species, they compact more food in their stomachs and absorb nutrients via more organs, such as the digestive grand and digestive duct appendages, in addition to cecum.

Published

2016

9. An invertebrate with a backbone.

Author

Larsen GD

Subjects

Animals, Biocompatible Materials, Tissue Scaffolds, Animal Shells, Sepia anatomy & histology, Sepia physiology

Published

2015

10. Emergence of sensory structures in the developing epidermis in sepia officinalis and other coleoid cephalopods.

Author

Buresi A, Croll RP, Tiozzo S, Bonnaud L, and Baratte S

Subjects

Animals, Animals, Newborn, Cephalopoda classification, Cephalopoda embryology, Cephalopoda metabolism, ELAV Proteins genetics, ELAV Proteins metabolism, Embryo, Nonmammalian, Epidermis innervation, Paired Box Transcription Factors genetics, Paired Box Transcription Factors metabolism, Peptide Hydrolases genetics, Peptide Hydrolases metabolism, Sensation physiology, Afferent Pathways embryology, Epidermis embryology, Epidermis growth & development, Epidermis metabolism, Gene Expression Regulation, Developmental, Sepia anatomy & histology, Sepia embryology, Sepia growth & development

Abstract

Embryonic cuttlefish can first respond to a variety of sensory stimuli during early development in the egg capsule. To examine the neural basis of this ability, we investigated the emergence of sensory structures within the developing epidermis. We show that the skin facing the outer environment (not the skin lining the mantle cavity, for example) is derived from embryonic domains expressing the Sepia officinalis ortholog of pax3/7, a gene involved in epidermis specification in vertebrates. On the head, they are confined to discrete brachial regions referred to as "arm pillars" that expand and cover Sof-pax3/7-negative head ectodermal tissues. As revealed by the expression of the S. officinalis ortholog of elav1, an early marker of neural differentiation, the olfactory organs first differentiate at about stage 16 within Sof-pax3/7-negative ectodermal regions before they are covered by the definitive Sof-pax3/7-positive outer epithelium. In contrast, the eight mechanosensory lateral lines running over the head surface and the numerous other putative sensory cells in the epidermis, differentiate in the Sof-pax3/7-positive tissues at stages ∼24-25, after they have extended over the entire outer surfaces of the head and arms. Locations and morphologies of the various sensory cells in the olfactory organs and skin were examined using antibodies against acetylated tubulin during the development of S. officinalis and were compared with those in hatchlings of two other cephalopod species. The early differentiation of olfactory structures and the peculiar development of the epidermis with its sensory cells provide new perspectives for comparisons of developmental processes among molluscs., (© 2014 Wiley Periodicals, Inc.)

Published

2014

11. Comparative morphology of changeable skin papillae in octopus and cuttlefish.

Author

Allen JJ, Bell GR, Kuzirian AM, Velankar SS, and Hanlon RT

Subjects

Animals, Connective Tissue anatomy & histology, Connective Tissue physiology, Decapodiformes classification, Microscopy, Electron, Scanning, Sepia anatomy & histology, Skin anatomy & histology, Decapodiformes anatomy & histology, Decapodiformes physiology, Ecosystem, Octopodiformes anatomy & histology

Abstract

A major component of cephalopod adaptive camouflage behavior has rarely been studied: their ability to change the three-dimensionality of their skin by morphing their malleable dermal papillae. Recent work has established that simple, conical papillae in cuttlefish (Sepia officinalis) function as muscular hydrostats; that is, the muscles that extend a papilla also provide its structural support. We used brightfield and scanning electron microscopy to investigate and compare the functional morphology of nine types of papillae of different shapes, sizes and complexity in six species: S. officinalis small dorsal papillae, Octopus vulgaris small dorsal and ventral eye papillae, Macrotritopus defilippi dorsal eye papillae, Abdopus aculeatus major mantle papillae, O. bimaculoides arm, minor mantle, and dorsal eye papillae, and S. apama face ridge papillae. Most papillae have two sets of muscles responsible for extension: circular dermal erector muscles arranged in a concentric pattern to lift the papilla away from the body surface and horizontal dermal erector muscles to pull the papilla's perimeter toward its core and determine shape. A third set of muscles, retractors, appears to be responsible for pulling a papilla's apex down toward the body surface while stretching out its base. Connective tissue infiltrated with mucopolysaccharides assists with structural support. S. apama face ridge papillae are different: the contraction of erector muscles perpendicular to the ridge causes overlying tissues to buckle. In this case, mucopolysaccharide-rich connective tissue provides structural support. These six species possess changeable papillae that are diverse in size and shape, yet with one exception they share somewhat similar functional morphologies. Future research on papilla morphology, biomechanics and neural control in the many unexamined species of octopus and cuttlefish may uncover new principles of actuation in soft, flexible tissue.

Published

2014

12. Cuttlefish skin papilla morphology suggests a muscular hydrostatic function for rapid changeability.

Author

Allen JJ, Bell GR, Kuzirian AM, and Hanlon RT

Subjects

Animals, Chromatophores physiology, Chromatophores ultrastructure, Connective Tissue anatomy & histology, Connective Tissue physiology, Connective Tissue ultrastructure, Hydrostatic Pressure, Microscopy, Confocal, Microscopy, Electron, Scanning, Muscle Contraction, Muscles anatomy & histology, Muscles physiology, Muscles ultrastructure, Pigmentation, Sepia ultrastructure, Skin anatomy & histology, Skin ultrastructure, Sepia anatomy & histology, Sepia physiology

Abstract

Coleoid cephalopods adaptively change their body patterns (color, contrast, locomotion, posture, and texture) for camouflage and signaling. Benthic octopuses and cuttlefish possess the capability, unique in the animal kingdom, to dramatically and quickly change their skin from smooth and flat to rugose and three-dimensional. The organs responsible for this physical change are the skin papillae, whose biomechanics have not been investigated. In this study, small dorsal papillae from cuttlefish (Sepia officinalis) were preserved in their retracted or extended state, and examined with a variety of histological techniques including brightfield, confocal, and scanning electron microscopy. Analyses revealed that papillae are composed of an extensive network of dermal erector muscles, some of which are arranged in concentric rings while others extend across each papilla's diameter. Like cephalopod arms, tentacles, and suckers, skin papillae appear to function as muscular hydrostats. The collective action of dermal erector muscles provides both movement and structural support in the absence of rigid supporting elements. Specifically, concentric circular dermal erector muscles near the papilla's base contract and push the overlying tissue upward and away from the mantle surface, while horizontally arranged dermal erector muscles pull the papilla's perimeter toward its center and determine its shape. Each papilla has a white tip, which is produced by structural light reflectors (leucophores and iridophores) that lie between the papilla's muscular core and the skin layer that contains the pigmented chromatophores. In extended papillae, the connective tissue layer appeared thinner above the papilla's apex than in surrounding areas. This result suggests that papilla extension might create tension in the overlying connective tissue and chromatophore layers, storing energy for elastic retraction. Numerous, thin subepidermal muscles form a meshwork between the chromatophore layer and the epidermis and putatively provide active papillary retraction., (Copyright © 2013 Wiley Periodicals, Inc.)

Published

2013

13. Inter-cohort growth patterns of pharaoh cuttlefish Sepia pharaonis (Sepioidea: Sepiidae) in Eastern Arabian Sea.

Author

Sasikumarl G, Mohamed KS, and Bhat US

Subjects

Animals, Female, Fisheries, India, Male, Oceans and Seas, Population Dynamics, Seasons, Sepia anatomy & histology, Sepia classification, Sex Factors, Sepia growth & development

Abstract

Sepia pharaonis is an important commercial species endemic to the tropical Indo-Pacific region. Despite its commercial significance, only few information on natural populations is available. This study was aimed to describe the aspects of size-composition, length-weight relationship, catch rates, seasonal recruitment and inter-cohort growth patterns of S. pharaonis population (Clade C), distributed along the Eastern Arabian Sea (South-West coast of India). For this, the Dorsal Mantle Length (DML) and weight of cuttlefishes was obtained from commercial trawl catches, from April 2002 to October 2006. Data was analyzed by normal length-weight methods such as von Bertalanffy. A total of 12454 cuttlefishes, ranging in length from four to 41cm were analyzed. Size-composition patterns discriminated two pulses in recruitment to the fishery, discernible by a decrease in the monthly mean size of the population. The DMLs of the two seasonal cohorts were subjected to modal-progression analysis using the Bhattacharya's method for the estimation of growth. The estimated parameters Linfinity and K in von Bertalanffy Growth Function (VBGF) were used to model growth curves in length for the cohorts. The first cohort, (post-monsoon cohort) which supports the major fishery, was composed of medium-sized, fast growing individuals, whereas the second cohort (pre-monsoon cohort), comprised of slow growing and large-sized individuals. There were differential growth characteristics between the sexes and the life span was estimated at less than 2.3 years for males and 2.1 years for females. Negative allometric growth in weight (W) with length (L) was observed for males (W=0.33069.L2.5389) and females (W=0.32542.L26057). The females were heavier compared to males at any given mantle length, and the males were found to attain larger ultimate lengths. The major fishing season for cuttlefish was from May to November, when higher monthly catch rates of 1.67-13.02kg/h were observed in comparison with 0.03-0.85kg/h in December-April. Seasonal catch rates indicated a migratory life cycle ofS. pharaonis between offshore and inshore coastal zones.

Published

2013

14. Cerebral correlates of visual lateralization in Sepia.

Author

Jozet-Alves C, Romagny S, Bellanger C, and Dickel L

Subjects

Aging, Animals, Brain metabolism, Dopamine metabolism, Norepinephrine metabolism, Optic Lobe, Nonmammalian cytology, Optic Lobe, Nonmammalian metabolism, Sepia growth & development, Sepia metabolism, Serotonin metabolism, Behavior, Animal physiology, Functional Laterality physiology, Sepia anatomy & histology

Abstract

The common cuttlefish, Sepia officinalis (cephalopod mollusc) has recently become a relevant model for studying the setting-up of brain asymmetry among invertebrates. As the animals age from 3 to 30 days post hatching, they progressively develop a left-turning bias resulting from an eye-use preference. The aim of this study is to investigate whether anatomical (vertical, peduncle, inferior buccal, and optic lobes) or neurochemical (monoamines in optic lobes) brain asymmetries are present in the cuttlefish brain at 3 or at 30 post hatching days; and whether these correlate with side-turning preferences. We here find brain and behavioral asymmetry only at 30 post hatching days. Cuttlefish displayed a significant population bias towards a larger right peduncle lobe, and higher monoamine concentration in the left optic lobe (i.e. serotonin, dopamine and noradrenaline). None of these brain asymmetries were correlated to the studied side-turning bias. However, we found individual variation in the magnitude of the vertical and optic lobes asymmetry. A striking correlation was found with the behavioral results: the larger the right optic lobe and the right part of the vertical lobe, the stronger the bias to turn leftwards. To our knowledge, this is the first study to demonstrate a relationship at the individual level between brain and behavioral asymmetries in invertebrates., (Copyright © 2012 Elsevier B.V. All rights reserved.)

Published

2012

15. Behavioral laterality and morphological asymmetry in the cuttlefish, Sepia lycidas.

Author

Lucky NS, Ihara R, Yamaoka K, and Hori M

Subjects

Animals, Behavior, Animal physiology, Functional Laterality physiology, Sepia anatomy & histology, Sepia physiology

Abstract

Behavioral laterality is widely found among vertebrates, but has been little studied in aquatic invertebrates. We examined behavioral laterality in attacks on prey shrimp by the cuttlefish, Sepia lycidas, and correlated this to their morphological asymmetry. Behavioral tests in the laboratory revealed significant individual bias for turning either clockwise or counterclockwise toward prey, suggesting behavioral dimorphism in foraging behavior. Morphological bias was examined by measuring the curvature of the cuttlebone; in some the cuttlebone was convex to the right (righty), while in others, the cuttlebone was convex to the left (lefty). The frequency distributions of an index of cuttlebone asymmetry were bimodal, indicating that populations were composed of two types of individuals: "righty" and "lefty." Moreover, an individual's laterality in foraging behavior corresponded with the asymmetry of its cuttlebone, with righty individuals tending to turn counterclockwise and lefty ones in the opposite direction. These results indicate that cuttlefish exhibit behavioral dimorphism and morphological antisymmetry in natural populations. The presence of two types of lateral morph in cuttlefish provides new information on the relationship between antisymmetric morphologies and the evolution of individual laterality in behavioral responses in cephalopods. The implications of these findings for the interpretation of ecological meaning and maintenance mechanisms of laterality in cuttlefish are also discussed.

Published

2012

16. Alternative sites of synaptic plasticity in two homologous "fan-out fan-in" learning and memory networks.

Author

Shomrat T, Graindorge N, Bellanger C, Fiorito G, Loewenstein Y, and Hochner B

Subjects

Animals, Brain anatomy & histology, Brain physiology, Female, Ganglionic Blockers pharmacology, Hexamethonium pharmacology, Learning, Long-Term Potentiation, Male, Memory, Neurons drug effects, Neurons physiology, Octopodiformes anatomy & histology, Sepia anatomy & histology, Species Specificity, Synaptic Transmission, Octopodiformes physiology, Sepia physiology

Abstract

Background: To what extent are the properties of neuronal networks constrained by computational considerations? Comparative analysis of the vertical lobe (VL) system, a brain structure involved in learning and memory, in two phylogenetically close cephalopod mollusks, Octopus vulgaris and the cuttlefish Sepia officinalis, provides a surprising answer to this question., Results: We show that in both the octopus and the cuttlefish the VL is characterized by the same simple fan-out fan-in connectivity architecture, composed of the same three neuron types. Yet, the sites of short- and long-term synaptic plasticity and neuromodulation are different. In the octopus, synaptic plasticity occurs at the fan-out glutamatergic synaptic layer, whereas in the cuttlefish plasticity is found at the fan-in cholinergic synaptic layer., Conclusions: Does this dramatic difference in physiology imply a difference in function? Not necessarily. We show that the physiological properties of the VL neurons, particularly the linear input-output relations of the intermediate layer neurons, allow the two different networks to perform the same computation. The convergence of different networks to the same computational capacity indicates that it is the computation, not the specific properties of the network, that is self-organized or selected for by evolutionary pressure., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

17. Characterization of the adhesive areas in Sepia tuberculata (Mollusca, Cephalopoda).

Author

von Byern J, Scott R, Griffiths C, Micossi A, Grunwald I, and Cyran N

Subjects

Adhesiveness, Animals, Carbohydrates analysis, Epithelial Cells metabolism, Epithelium physiology, Sepia physiology, Skin cytology, Tissue Adhesives chemistry, Epithelial Cells cytology, Epithelium anatomy & histology, Sepia anatomy & histology, Skin anatomy & histology

Abstract

Adhesion in cephalopods is either mechanical, involving a reduced-pressure system of the arm and tentacle suckers, or is chemically mediated by special adhesive gland structures (as proposed for Euprymna, Idiosepius, and Nautilus). Four species of Sepia (S. typica, S. papillata, S. pulchra, and S. tuberculata) possess grooved structures on the ventral mantle surface and on the fourth arm pair, which are used to attach mechanically to the substratum. Because these areas are often partly covered with sand or debris, it has been hypothesized that chemical substances were involved in this attachment process. This study provides a histochemical and ultrastructural description of the glandular epithelium in the adhesive area of Sepia tuberculata. Two specific glandular cells (Type 1 and Type 2) are present in the epithelium, which differ clearly in their granule size and cellular structure. The aggregation of both cell types and their simultaneous secretion suggest that the secretions of both cell types work synergistically providing a two-component adhesive system which supports the primarily mechanical sucker adhesion by making the arm surface sticky., (Copyright © 2011 Wiley-Liss, Inc.)

Published

2011

18. FaRP cell distribution in the developing CNS suggests the involvement of FaRPs in all parts of the chromatophore control pathway in Sepia officinalis (Cephalopoda).

Author

Aroua S, Andouche A, Martin M, Baratte S, and Bonnaud L

Subjects

Animals, Central Nervous System anatomy & histology, Central Nervous System embryology, Central Nervous System immunology, Image Processing, Computer-Assisted, Immunohistochemistry, Microscopy, Organogenesis, Peripheral Nervous System anatomy & histology, Peripheral Nervous System embryology, Peripheral Nervous System immunology, Sepia anatomy & histology, Sepia immunology, Skin Pigmentation, FMRFamide physiology, Sepia embryology

Abstract

The FMRFamide-related peptide (FaRP) family includes a wide range of neuropeptides that have a role in many biological functions. In cephalopods, these peptides intervene in the peculiar body patterning system used for communication and camouflage. This system is particularly well developed in the cuttlefish and is functional immediately after hatching (stage 30). In this study, we investigate when and how the neural structures involved in the control of body patterning emerge and combine during Sepia embryogenesis, by studying the expression or the production of FaRPs. We detected FaRP expression and production in the nervous system of embryos from the beginning of organogenesis (stage 16). The wider FaRP expression was observed concomitantly with brain differentiation (around stage 22). Until hatching, FaRP-positive cells were located in specific areas of the central and peripheral nervous system (CNS and PNS). Most of these areas were implicated in the control of body patterns, suggesting that FaRPs are involved in all parts of the neural body pattern control system, from the 'receptive areas' via the CNS to the chromatophore effectors., (Copyright © 2011 Elsevier GmbH. All rights reserved.)

Published

2011

19. Protein nitration is specifically associated with melanin production and reveals redox imbalance as a new correlate of cell maturation in the ink gland of Sepia officinalis.

Author

Fiore G, Mattiello T, Tedeschi G, Nonnis S, d'Ischia M, and Palumbo A

Subjects

Animals, Nitric Oxide metabolism, Nitric Oxide Synthase genetics, Nitric Oxide Synthase metabolism, Oxidation-Reduction, Peptide Fragments analysis, Peroxidase metabolism, Signal Transduction physiology, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Melanins biosynthesis, Nitrates chemistry, Nitrates metabolism, Sepia anatomy & histology, Sepia physiology

Published

2009

20. Perception of visual texture and the expression of disruptive camouflage by the cuttlefish, Sepia officinalis.

Author

Kelman EJ, Baddeley RJ, Shohet AJ, and Osorio D

Subjects

Animals, Ecosystem, Humans, Principal Component Analysis, Sepia anatomy & histology, Sepia physiology, Visual Perception

Abstract

Juvenile cuttlefish (Sepia officinalis) camouflage themselves by changing their body pattern according to the background. This behaviour can be used to investigate visual perception in these molluscs and may also give insight into camouflage design. Edge detection is an important aspect of vision, and here we compare the body patterns that cuttlefish produced in response to checkerboard backgrounds with responses to backgrounds that have the same spatial frequency power spectrum as the checkerboards, but randomized spatial phase. For humans, phase randomization removes visual edges. To describe the cuttlefish body patterns, we scored the level of expression of 20 separate pattern 'components', and then derived principal components (PCs) from these scores. After varimax rotation, the first component (PC1) corresponded closely to the so-called disruptive body pattern, and the second (PC2) to the mottle pattern. PC1 was predominantly expressed on checkerboards, and PC2 on phase-randomized backgrounds. Thus, cuttlefish probably have edge detectors that control the expression of disruptive pattern. Although the experiments used unnatural backgrounds, it seems probable that cuttlefish display disruptive camouflage when there are edges in the visual background caused by discrete objects such as pebbles. We discuss the implications of these findings for our understanding of disruptive camouflage.

Published

2007

21. Cephalopod dynamic camouflage.

Author

Hanlon R

Subjects

Animals, Biological Evolution, Cephalopoda anatomy & histology, Octopodiformes anatomy & histology, Octopodiformes physiology, Sepia anatomy & histology, Sepia physiology, Time Factors, Visual Perception physiology, Adaptation, Physiological physiology, Cephalopoda physiology, Color

Published

2007

22. Visual ecology: hiding in the dark.

Author

Warrant EJ

Subjects

Animals, Predatory Behavior, Sepia anatomy & histology, Behavior, Animal physiology, Color, Darkness, Sepia physiology

Abstract

The ability of many animals to camouflage themselves against a background is a well-known daytime phenomenon. Now it has even been found to occur at night, highlighting the reality of nocturnal visual predation.

Published

2007

23. Distribution of neurokinin A-like and serotonin immunoreactivities within the vertical lobe complex in Sepia officinalis.

Author

Boyer C, Maubert E, Charnay Y, and Chichery R

Subjects

Animals, Axons metabolism, Brain anatomy & histology, Immunohistochemistry, Learning physiology, Male, Sepia anatomy & histology, Brain metabolism, Neurokinin A metabolism, Neurons metabolism, Sepia metabolism, Serotonin metabolism

Abstract

Immunohistochemistry, using antibodies raised against mammalian neurokinin A (NKA) and serotonin (5-HT), was applied in double-staining experiments to map these molecules within the vertical lobe complex (inferior frontal, superior frontal, post-frontal, vertical, subvertical and precommissural lobes). NKA-like and 5-HT immunoreactivities were detected in all the lobes of the vertical lobe complex but were never colocalized in cell bodies or fibres. Except for the cell layers of the superior frontal lobe, both types of labelled cell bodies were observed in all the lobes. Both types of immunoreactive fibres were detected in all the neuropils and interestingly revealed clear subdivisions within some lobes, e.g., 5-HT-IR fibres were more abundant in the peripheral part of the vertical lobe whereas NKA-IR ones were widely observed in both the peripheral and central parts. In cephalopods, the vertical lobe complex is involved in learning and memory; thus, our results strongly suggest that one or more NKA-like and 5-HT molecules may function as neurochemical messengers in these cognitive processes.

Published

2007

24. Allometry of thermal limitation in the cephalopod Sepia officinalis.

Author

Melzner F, Bock C, and Pörtner HO

Subjects

Animals, Sepia anatomy & histology, Skin Physiological Phenomena, Temperature, Oxygen Consumption, Sepia physiology

Abstract

Cuttlefish (Sepia officinalis) routine metabolic rate was determined in response to acute thermal changes at a rate of 1 degrees C h(-1) for a variety of animal sizes (15-496 g wet mass, laboratory reared at 15 degrees C). In a thermal frame of 11 to 23 degrees C, oxygen consumption rates (MO(2), in mumol O(2) g(-1) min(-1)) were observed to rise with increasing temperature (T, in degrees C) and to decline with increasing body mass (m, in g), according to the formula: ln MO(2)=-3.3+0.0945T-0.215 ln m (R(2)=0.93). Outside the above thermal window, animals were not able to increase MO(2) at similar rates, indicating a beginning oxygen limitation of metabolism. Large animals (>100 g body mass) already displayed lower than expected MO(2) values at 8 and 26 degrees C, while smaller animals (15 g wet mass) were characterized by a wider thermal window (MO(2) values deviated from expected rates at 5 and 29 degrees C). Morphometric data of cuttlefish mantle skin area was obtained to discuss size - related effects of skin respiration potential on thermal tolerance. Cuttlefish growth was observed to be isometric, as constant 'Vogel numbers' of 4.2 indicated (animal body masses: 11 to 401 g). In the same mass range, specific mantle surface area declined three-fold from 10.7 (0.24) (means+/-SD) to 3.3 (0.52) cm(2) g(-1). Thus, increased thermal tolerance in smaller animals may be enabled by a higher skin respiration potential due to higher specific skin surface areas. An elevated fraction of MO(2) provided by means of skin respiration in small animals could relieve the cardiovascular system, which previously has been found a major limiting component during acute thermal stress in cuttlefish.

Published

2007

25. [The preparation of a new hydroxyapatite and the study on its cytocompatibility].

Author

Tao K, Mao T, Chen F, and Liu X

Subjects

Animals, Bone Substitutes chemistry, Bone Substitutes toxicity, Cells, Cultured, Durapatite chemistry, Durapatite toxicity, Materials Testing, Osteoblasts cytology, Rabbits, Sepia anatomy & histology, Spine anatomy & histology, Spine chemistry, Tissue Engineering, Bone Substitutes chemical synthesis, Durapatite chemical synthesis, Osteoblasts drug effects

Abstract

The cuttlebones, harvested from cuttles, undergo the chemical reaction in high temperature and high pressure for a certain time. The products are qualitatively analysed, and spacial structure observation and cytocompatibility are tested. The results show that the chemical component of the cuttlebone is CaCO3 and the crystal type is aragonite. Cuttlebones undergo a hydro-thermal reaction, and thus transform into hydroxyapatite-that is, the cuttlebone-transformed hydroxyapatite(CBHA). The CBHA materials have the interconnected microporous network structures. Under the high magnification, CBHAs appear to have many micro-spheres, thus construct a new self-assembled nano-material system. The marrow stromal osteoblasts can adhere to and proliferate well on the surface of the CBHAs. These results show that CBHAs have good biocompatibility. Therefore, it can be a potential candidate scaffold for bone tissue engineering.

Published

2006

26. Signaling to the enemy? Body pattern expression and its response to external cues during hunting in the cuttlefish Sepia officinalis (Cephalopoda).

Author

Adamo SA, Ehgoetz K, Sangster C, and Whitehorne I

Subjects

Animals, Cognition, Learning, Sepia anatomy & histology, Animal Communication, Cues, Predatory Behavior, Sepia physiology, Skin Pigmentation physiology

Abstract

Cuttlefish can rapidly alter their appearance by using neurally controlled chromatophore organs. This ability may provide a window into their cognitive capacity. We test whether the changes in body pattern that occur during hunting depend on context. If they do, then it may be possible to use these changes to study cephalopod cognition while the animal is engaged in ecologically relevant tasks. We found consistent individual differences in the tendency of cuttlefish to hunt with the first two arms raised. We also found that cuttlefish usually darken their skin after they seize a prey item. This darkening is observed regardless of the identity of the prey (fish, crab, or shrimp), prey context (buried in sand, in a bare tank, or on top of a rock pile), or the presence of a sudden stimulus. The sudden stimulus was created by presenting an overhead model bird to the cuttlefish. The model induced components of the Deimatic Display, which is a form of antipredator behavior, suggesting that the model was perceived as a potential threat. Passing Cloud displays and the Darkening of the arms were significantly reduced after exposure to the model bird. The effect of a potential predator on body pattern expression during hunting suggests it may be possible to use these changes as a sensitive indicator of ecologically relevant learning.

Published

2006

27. Symmetrical crypsis and asymmetrical signalling in the cuttlefish Sepia officinalis.

Author

Langridge KV

Subjects

Adaptation, Physiological physiology, Animals, Pigmentation genetics, Pigmentation physiology, Sepia anatomy & histology, Animal Communication, Sepia physiology

Abstract

The salience of bilateral symmetry to humans has led to the suggestion that camouflage may be enhanced in asymmetrical patterns. However, the importance of bilateral symmetry in visual signals (and overall morphology) may constrain the evolution of asymmetrical camouflage, resulting in the bilaterally symmetrical cryptic patterns that we see throughout the animal kingdom. This study investigates the cuttlefish (Sepia officinalis), which can control the degree of symmetry in its coloration. Ten juvenile S. officinalis were filmed in two behavioural contexts (cryptic and threatened) to test the prediction that cryptic patterns will be expressed more asymmetrically than an anti-predator signal known as the 'deimatic display'. Cryptic body patterns, particularly those with a disruptive function, were found to exhibit a high degree of bilateral symmetry. By contrast, the components of the deimatic display were often expressed asymmetrically. These results are contrary to the predicted use of symmetry in defensive coloration, indicating that the role of symmetry in both crypsis and visual signalling is not as straightforward as previously suggested.

Published

2006

28. Adhesive mechanisms in cephalopods: a review.

Author

von Byern J and Klepal W

Subjects

Adhesiveness, Animals, Cephalopoda classification, Cephalopoda ultrastructure, Decapodiformes anatomy & histology, Decapodiformes physiology, Decapodiformes ultrastructure, Marine Biology, Microscopy, Electron, Transmission, Nautilus anatomy & histology, Nautilus physiology, Nautilus ultrastructure, Sepia anatomy & histology, Sepia physiology, Sepia ultrastructure, Cephalopoda anatomy & histology, Cephalopoda physiology

Abstract

Several genera of cephalopods (Nautilus, Sepia, Euprymna and Idiosepius) produce adhesive secretions, which are used for attachment to the substratum, for mating and to capture prey. These adhesive structures are located in different parts of the body, viz. in the digital tentacles (Nautilus), in the ventral surface of the mantle and fourth arm pair (Sepia), in the dorsal epidermis (Euprymna), or in the dorsal mantle side and partly on the fins (Idiosepius). Adhesion in Sepia is induced by suction of dermal structures on the mantle, while for Nautilus, Euprymna and Idiosepius adhesion is probably achieved by chemical substances. Histochemical studies indicate that in Nautilus and Idiosepius secretory cells that appear to be involved in adhesion stain for carbohydrates and protein, whilst in Euprymna only carbohydrates are detectable. De-adhesion is either achieved by muscle contraction of the tentacles and mantle (Nautilus and Sepia) or by secretion of substances (Euprymna). The de-adhesive mechanism used by Idiosepius remains unknown.

Published

2006