An electron-microscope study of periostracum formation in some marine bivalves. II. The cells lining the periostracal groove

The histology and ultrastructure of the epithelial cells of the outer and middle mantle folds of the bivalves Mytilus edulis (L), Cardium edule (L), Macoma balthica (L) and Nucula sulcata Bronn are described. The cells lining the inner face of the outer fold exhibit a prominent granular endoplasmic reticulum, and Golgi complexes which are concerned with the elaboration of granules and vesicles eventually incorporated into the periostracum. A gradual reduction in the protein synthetic apparatus occurs towards the tip of the fold. Within the cells, it is proposed that the ovoid inclusion bodies are lysosomes and that they control the rate of secretion. The cells of the middle fold are cuboidal in appearance. Those of M. edulis and N. sulcata exhibit prominent granules, whereas those of C. edule and M. balthica possess vesicles. The cells of M. edulis differ from the others in possessing stout bundles of filaments, which occupy large areas of the cell and constitute a cell web. The cells of the epithelium in all cases do not appear to be implicated in periostracum formation.     

Seasonal cycle of lysosomal enzyme activities in the mantle tissue and isolated cells from the musselMytilus edulis

InMytilus edulis L., gametogenesis takes place in the mantle at the expense of the connective storage tissue. There are two main types of storage cells: vesicular (VC) cells storing large amounts of glycogen and adipogranular (ADG) cells containing large numbers of protein granules, lipid droplets and lesser amounts of glycogen. One of the ways in which stored reserves can be mobilized for gamete formation is by controlled autophagy, in which the cellular constituents are degraded by lysosomes. Mussels were collected from the Menai Strait, North Wales, and monthly measurements made, over two years (1984–1986), of the activities of lysosomal acid hydrolases (acid phosphatase,-N-acetyl-D-glucosaminidase and-glucuronidase) and Cathepsins B and L in the mantle tissue, isolated ADG cells, low-density cells and, during spawning, in the mature oocytes of female mussels. The lysosomal proteinases, Cathepsins B, L and H, were further characterised by activation with thiol compounds and inhibition with thiol blockers and by leupeptin. Because of the low activity in the mantle tissue ofM. edulis, Cathepsin H was not assayed on a seasonal basis. There was a general increase in lysosomal enzyme activity during the winter, which can be related to increased autolysis in the storage cells and to the process of maturation in the developing oocytes. The activity of Cathepsin B was highest in the ADG and low-density cells, implying an important role in proteolysis within the ADG cells. By contrast, Cathepsin L displayed the highest activity in the mature oocytes, suggesting a major function of Cathepsin L in the development and maturation of the oocytes. Two different-glucosidase activities were measured in the monthly assays, one with a pH optimum of 4.5 (acid) and the other at pH 7.5 (neutral). Highest activities of the acid-glycosidase were found in the low-density cells, but there were no significant seasonal changes in the mantle tissue as a whole. Activities of the neutral-glucosidase were low in the ADG cells and mature oocytes, but showed high activities in the mantle tissue, with marked seasonal changes that corresponded to the mobilization of glycogen reserves in the VC cells.     

Investigation of cell proliferation and differentiation in the mantle of <Emphasis Type="Italic">Pinctada </Emphasis><Emphasis Type="Italic">fucata</Emphasis> (Bivalve,Mollusca)

The mantle of the pearl oyster Pinctada fucata was adopted for the proliferation profile study in our work and a proliferation hot spot was found in the outer epithelia of mantle central zone using the BrdU immunohistochemistry method. This result contradicts the previous research that the mantle has numerous growth centers all over the mantle epithelium, with the same proliferation activity throughout the whole mantle outer epithelial cells. This is the first report on the different proliferation features on the whole mantle where Alcian Blue/PAS staining analysis and ultrastructural observation with the aid of transmission electron microscope (TEM) demonstrated distinct features of the epithelium in four different regions of the mantle. Results from the present investigation displayed that in the outer epithelium of the marginal zone in mantle outer fold, organelles such as mitochondria and endoplasmic reticulum (ER) were well-developed and double membrane bounded vesicles were present; in the outer epithelia of mantle central zone, stem-like cells with a high ratio of nucleus to cytoplasm and comparatively undeveloped organelles were detected. Together with the observations of the cell proliferation profile of different regions of the mantle, a hypothetic model for the proliferation and differentiation of the pearl oyster’s mantle is proposed: there exists a proliferation “hot spot” in the outer epithelial cells of central zone and the proliferation ability decreases progressively from this “hot spot” towards the marginal zone; the whole mantle’s differentiation occurs continuously with its growth and the direction is from the proliferation ‘hot spot’ (central zone) towards the marginal zone. Furthermore, another interesting result was found when the proliferation rate was investigated together with the tidal rhythm: the proliferation activity was found to be closely correlated with the tidal rhythm, indicating that the mantle outer epithelia’s proliferation rhythm might be the impetus of the shell’s daily growth bands.     

Studies on the defensive behaviour ofHypselodoris species (Gastropoda: Nudibranchia): Ultrastructure and chemical analysis of mantle dermal formations (MDFs)

The mantle dermal formations (MDFs) ofHypselodoris webbi (D'orbigny, 1839), andH. cantabrica (Bouchet and Ortea, 1980) are globular sub-epidermal structures located in the cephalic and caudal regions. Histologically they consist of an accumulation of vacuolate cells surrounded by a basal lamina and an outer muscular capsule. Chemical analysis ofH. webbi MDFs reveals the presence of high concentrations of longifolin, a well known deterrent furanosesquiterpenoid that had been previously isolated from this species. In the present paper it is demonstrated that the great majority of longifolin accumulated in the mantle ofH. webbi is stored in the MDF vacuolar cells. This finding strongly suggests that such structures act as chemical weapons against predation, mainly protecting vital organs such as the head, rhinophores and gills.     

Role of carbonic anhydrase in the supply of inorganic carbon to the giant clam—zooxanthellate symbiosis

The mechanism whereby inorganic carbon (C_i) is acquired by the symbiotic association between the giant clam (Tridacna derasa) and zooxanthellae (Symbiodinium sp.) has been investigated. C_i in the haemolymph of the clam is in equilibrium with the surrounding sea water. The photosynthesis rate exhibited by the intact clam varies as a function of the C_i concentration in the clam haemolymph. The gill tissue contains high carbonic anhydrase activity which may be important in adjusting the C_i equilibrium between haemolymph and sea water. Zooxanthellae (Symbiodinium sp.) isolated from the clam mantle prefer CO₂ to HCO ₃ ^- as a source of inorganic carbon. The zooxanthellae have low levels of carbonic anhydrase on the external surface of the cell; however, mantle extracts display high carbonic anhydrase activity. Carbonic anhydrase is absent from the mantle of aposymbiotic clams (T. gigas), indicating that this enzyme may be essential to the symbiosis. The enzyme is probably associated with the zooxanthellae tubes in the mantle. The results indicate that carbonic anhydrase plays an important role in the supply of carbon dioxide within the clam symbiosis.     

UV-absorbing substances in zooxanthellate and azooxanthellate clams

The effects of UV-A and UV-B radiation on photosynthesis of zooxanthellae within the siphonal mantle of the giant clam, Tridacna crocea, and in isolation were studied. While UV-B irradiation (2.4 W m⁻², 20 min) completely suppressed photosynthesis of the isolated zooxanthellae, it had little effect on their photosynthetic ability if they were irradiated while within the siphonal mantle of the host tissue. Chemical analysis of the siphonal mantle of T. crocea showed the presence of significant amounts of mycosporine-like amino acids (MAAs), which absorb UV-A and -B light. However, no MAA was detected in the isolated zooxanthellae. MAAs were concentrated in the siphonal mantle and kidney tissues in comparison with other tissues. In the siphonal mantle, MAA concentrations were the highest in the outermost surface layer where most of the zooxanthella cells resided. This indicates that the zooxanthellae are protected from UV radiation by a screen of concentrated MAAs in the host clam. Aside from T. crocea, significant amounts of MAAs were found not only in other zooxanthellate clams, such as T. derasa, Hippopus hippopus, Colculum cardissa and Fragum unedo, but also in a closely related azooxanthellate clam, Vasticardium subrugosum. On the other hand, no MAA was detected in any of the zooxanthellae from these zooxanthellate clams. No MAA was detected in the tissues of a deep-sea bivalve, Calyptogena soyoae. Although MAAs seem to block strong UV radiation in the shallow-water clam, they are probably not essential for the clam's life in the dark. MAAs in shallow-water clams may be derived from food and accumulated in their tissues, especially in the siphonal mantle and kidney. Received: 29 November 1996 / Accepted: 13 January 1997     

Scanning and transmission electron microscope study of specialized mantle structures in dorid nudibranchs (Gastropoda: Opisthobranchia: Anthobranchia)

Mantle surfaces of the dorid nudibranchs Rostanga arbutus and Jorunna sp. were examined using scanning and transmission electron microscopy, and two specialized structures are described. These are caryophyllidia and mantle rim organs; the latter being described for the first time. Caryophyllidia occur in large numbers (several thousand) uniformly distributed over the entire upper surface, while the mantle rim organs, numbering only 40 to 60, are restricted to the upper mantle margin. Caryophyllidia are minute (40 to 50 m diam), erect tubercles supported internally by 4 to 7, vertical, calcareous spicules which emerge in a crown surrounding an apical knob. Caryophyllidia display a high level of spicular organization and incorporate a complex muscle system at their base. The apical knob is formed from specialized epidermis capping a sub-epithelial ganglion. The highly organized structure of the caryophyllidium indicates its potential importance as a new character in dorid taxonomy and phylogeny. Mantle rim organs (80 to 300 m diam) contain large numbers of vacuolated cells and cells containing pellet-shaped nodules.     

Transversal profiles of carbon assimilation in the fronds of three Laminaria species

The brown macroalgae Laminaria digitata (Huds.) Lamour., L. hyperborea (Gunn.) Foslie, and L. saccharina (L.) Lamour. (Laminariales, Phaeophyceae) have been investigated for carbon assimilation and assimilate biosynthesis in different tissues (meristoderm, cortex, medulla) of stipes and blades. Carboxylation via ribulose-1,5-bisphosphate carboxylase (EC 4.1.1.39) and phosphoenolpyruvate carboxykinase (EC 4.1.32) follows a transversal gradient from the outer to the inner tissues with maximum activity of enzymatic CO₂ fixation in the meristoderm. Such transversal profiles are also recorded for photosynthetic and dark carbon assimilation as well as for kinetics of assimilate ¹⁴C-labelling in isolated tissues. Differential chemical constitution of the blade and stipe tissues examined and results from assimilate biosynthesis are discussed with regard to a transversal translocation of photosynthates from meristodermal to cortical and medullar cells.     

Ultrastructure of the ovary and oogenesis in the jellyfish Linuche unguiculata and Stomolophus meleagris,with a review of ovarian structure in the Scyphozoa

Ovarian structure and oogenesis has been examined in six scyphozoan species including the semaeostome Diplumularis antarctica Maas, 1908 (collected in 1987 in McMurdo Sound, Antarctic), the rhizostomes Cassiopea xamachana Bigelow, 1892 (collected in Belize in 1988), and Stomolophus meleagris L. Agassiz, 1862 (collected in Ft. Pierce Inlet in 1988), and the coronates Periphylla periphylla (Peron and Lesueur, 1810), Nausithoe atlantica Broch, 1914 (both collected in the Bahamas in 1988), and Linuche unguiculata (Schwartz, 1788) (collected in Nassau Harbor, Bahama Islands in 1989). Based on these findings and information on five other scyphozoan species from additional literature sources, at least two fundamentally different types of ovaries exist in the Scyphozoa. In semaeosotome and rhizostome species, oocytes develop in close association with specialized gastrodermal cells called trophocytes which may serve a nutritive function. However, coronate species lack trophocytes and oocytes develop freely in the mesoglea. The ovaries of S. meleagris and L. unguiculata are used as models to represent the ultrastructural events occurring during oogenesis in species having trophocytes and those lacking them, respectively. In both L. unguiculata and S. meleagris, the ovaries arise as evaginations of the gastrodermis in the floor of interradial pouches. Germ cells appear to originate from endodermally-derived gastrodermal cells and migrate into the mesoglea prior to vitellogenesis. In L. unguiculata, the oocytes develop freely within the mesoglea throughout vitellogenesis, while in S. meleagris each oocyte maintains contact with specialized gastrodermal cells called trophocytes. In the vitellogenic oocytes of both species, numerous invaginations of the oolemma result in the formation of intraooplasmic channels throughout the ooplasm. These channels are intimately associated with cisternae of rough endoplasmic reticulum and may play some role in yolk precursor uptake by substantially increasing the surface area of the oocyte. Vitellogenesis is similar in both species and involves the autosynthetic activity of the Golge complex and rough endoplasmic reticulum, and the heterosynthetic incorporation of yolk precursors through receptor-mediated endocytosis. However, in the oocytes of S. meleagris, the trophocytes probably play a role in the transfer of nutrients from the gastrovascular cavity to the oocyte. The present study suggests that scyphozoans were among the first metazoans to develop ovarian accessory cells during their reproductive evolution. The trophocyte-oocyte association observed in some scyphozoans is similar to but structurally less complex than the trophonema-oocyte association described from anthozoans. Scyphozoan ovarian morphology helps support the view that the Scyphozoa share a closer phylogenetic relationship with the Anthozoa than with the Hydrozoa.     

Functional morphology of the gonads of the articulate brachiopodTerebratulina retusa

The reproductive anatomy, and ultrastructural features of the gonads of the articulate brachiopodTerebratulina retusa (Linnaeus), are documented based on collections made between October 1985 and October 1986 from the Firth of Lorn, west coast of Scotland. This species is dioecious, and maturity is achieved in both sexes at shell lengths greater than ~5.5 mm. There is no obvious external sexual dimorphism except for slight differences in the coloration of the gonads; testes are white/cream, ovaries are yellow/orange. The gonads occur as four palmate lobes, a pair in each valve. Gonads are formed within a mantle sinus (vascula genitalia), which is an anterior extension of the coelom, that opens posteriorly into the visceral cavity and to the exterior via a pair of metanephridia. The latter serve as gonoducts during spawning. Gametes are borne on genital lamellae formed from a reticulate lattice of connective tissue. The lamellae are an extension of the ileoparietal band and are fused along one margin to the inner mantle membrane. Developing oocytes are closely affixed to the genital lamellae and originate from a pool of proliferating germ cells at its base. Vitellogenic oocytes that are at an advanced stage are released from the genital lamellae, but are retained within thevascula genitalia. Liberated oocytes continue to accumulate yolk and eventually occlude thevascula genitalia, before being spawned. Coelomocytes were identified within the gonads. In spent females these cells appear to be phagocytic and involved in the resorption of necrotic material, while in the male they may serve as nutritive cells.     

Annual cycle of expression of connective tissue polypeptide markers in the mantle of the musselMytilus galloprovincialis

We suggest that gonad development in the mantle tissue of the bivalve molluscMytilus galloprovincialis Lmk. is an example of epithelial/mesenchymal interactions (i.e. soma/germline interactions) and morphogenesis in the adult state. According to this concept, the aim of the present study was to use biochemical and immunochemical methods for identifying and characterizing the mantle cell polypeptide markers whose expression is seasonally and morphogenetically regulated. We showed for the first time thatM. galloprovincialis mantle, of both males and females, contains polypeptides (with an apparent mol. wt of 45 to 53 kDa) specific for connective tissue (mantle connective tissue polypeptides; MCTPs). Electrophoretic, immunoblotting and immunofluorescent experiments demonstrated that MCTPs are primarily localized in the adipogranular (ADG) cells, and their expression in the mantle is seasonally regulated. There is a positive correlation between MCTP expression and connective tissue volume in the mantle. MCTPs are overexpressed during the rest period, when the mantle consists of connective tissue mainly, whereas mature gonads contain only trace amounts of MCTPs. Moreover, there is a temporal correlation between the onset and decrease of MCTP expression and the appearance and disappearance of the ADG cells in the mantle. MCTP localization in the mantle tissue should not be associated with the ADG cells only, because positive immunofluorescence was also detected in follicle membranes (but not in germ cells) and superficial mantle epithelium. Using immunoblotting and immunofluorescence, MCTPs were found in the connective tissue of the mantle, posterior adductor muscle and visceral mass, but not gills, foot or hepatopancreas. Possible mechanisms by which MCTPs could participate in the annual processes of mantle gonad/connective tissue development and involution are discussed.     

Cross-shelf distribution of copepods and fish larvae across the central Great Barrier Reef

The distribution of total dry weight of zooplankton, copepod numbers and ichthyoplankton across the outer continental shelf in the central Great Barrier Reef was examined at bi-weekly intervals for three months over summer of 1983. Copepods were sampled (236 m net) within 10 m of the surface and within 10 m of the bottom. Mean densities in surface waters decreased markedly from the mid-shelf to outer shelf and the Coral Sea, but no cross-shelf gradient occurred in the bottom-water. Densities of copepods on the mid-shelf (surface and bottom waters) and in bottom-waters of the outer shelf were typically ca. 400 m^–3. Significantly lower densities (ca. 100 m^–3) occurred in surface waters of the outer shelf, except during outbursts of Acartia australis, when densities in these waters differed little from those elsewhere on the shelf. In oceanic waters, 10 km from the outer shelf station, copepod densities in surface waters were ca. 40 m^–3. Four of the five most abundant copepod taxa in surface waters, Paracalanus spp., Eucalanus crassus, Acrocalanus gracilis and Canthocalanus pauper, tended to be most abundant at the mid-shelf end of the transect. Acartia australis was sporadically very abundant in surface waters of the outer shelf, as was Paracalanus spp. in bottom-water of the outer shelf. An assemblage of Coral Sea species of copepod occurred in bottom-water of the outer shelf during two major intrusions, but not at other times. Densities of all common species varied considerably between cruises. Maximum densities of all common species except A. australis tended to be associated with diatom blooms linked to intrusions but a bloom did not necessarily mean all common species were abundant. Fish larvae included both reef and non-reef taxa, with reef taxa predominating on the outer shelf (approx 2:1 in density of individuals) and non-reef taxa dominating in nearshore samples (approx 2:1). Nine of the ten most abundant taxa analysed showed highly significant variation in numbers among stations and all but one of these also exhibited significant station x cruise interactions. Interactions generally reflected changes in the rank importance of adjacent stations from one cruise to the next or lack of any significant cross-shelf variation on some cruises where overall abundance of the taxa was low.     

Effect of high temperatures on the ultrastructure of Leydig cells in Mytilus galloprovincialis

Individuals of the mussel Mytilus galloprovincialis (L), collected from the Black Sea, were subjected to relatively high temperatures (25°, 28° and 30°C) for 60 h Ultrastructural studies on Leydig cells of the mantle indicated progressive modifications in their structure. Mainly, we established that a continuous decrease of glycogen quantity in the cells took place as the temperature raised, while the lipid content increased, up to 28°C. Between 28° and 30°C the lipid content decreased as a result of a pronounced degradation process. An increase of membrane permeability and the disturbance in the synthesis of mucoproteic secretory granules were observed. It is concluded that for Mytilus galloprovincialis the thermal adaptation zone ranges between 25° and 28°C. 28°C is the upper tolerable limit temperature, while 30°C acts as a lethal temperature.     

Exfoliation of epithelial cells by the scallop Placopecten magellanicus : seasonal variation and the effects of elevated water temperatures

Previous studies have shown that large numbers of ciliated and nonciliated epithelial cells (diam.: 6 to 15 μm) are released by adult sea scallops, Placopecten magellanicus (Gmelin), during summer months in Newfoundland when water temperatures are at a maximum and gonads are well developed. Such exfoliation of cells could be a response to stresses associated with elevated water temperatures and/or spawning activity. In the present study an electronic particle counter/sizer was used to further investigate the factors that influence exfoliation of epithelial cells by juvenile and adult scallops throughout the year. We observed release of epithelial cells from juveniles, and from adults collected in months when gametogenic activity was minimal, indicating that exfoliation does not occur as a result of reproductive activity alone. SEM analysis revealed little difference in surface characteristics of the gills, mantle and gonad between scallops that had released cells and those that had not, suggesting that exfoliation of small numbers of cells may be a consequence of cellular turnover and normal physiological function. Adult scallops were monitored in a second experiment to determine the effects of raising water temperatures from 8.5 to 14.7 and to 21.0 °C on the frequency (proportion) and rate of cellular exfoliation. Only at the highest experimental temperature (21.0 °C) were exfoliation rates significantly higher than rates recorded at 8.5 or 14.7 °C. SEM analyses revealed some damage to gill, mantle and gonad tissues when scallops were exposed to 14.7 and then to 21.0 °C for a total of 8 d. Received: 21 August 1996 / Accepted: 13 September 1996     

An electron-microscope investigation into the distribution of polyphenols in the periostracum and cells of the inner face of the outer fold of Mytilus edulis

Polyphenols were located in all the layers of the periostracum and in inclusion bodies in the inner face of the outer-fold cells of Mytilus edulis L. Results, after 4 days periostracum repair, show that the proto-ostracal material is deposited in distinct layers. Inclusion bodies in the cells of the inner face of the outer fold appear to give rise to the polyphenols in the proto-ostracal material.     

Fine structure of some prosobranch ospharadia

The fine structure of the osphradia of Buccinum undatum 1. three Hawaiian Conus spp., Nassarius reticulatus (L), Nucella lapillus (L) and Littorina littorea (L) was examined. There is a remarkable uniformity in the arrangement of ultrastructural cell types in all the ospharadia investigated. The marginal glandular region is characterised by a single layer of cells, bearing a regular pallisade of microvilli and including two types of mucous cell. The epithelium of the sensory region is several cells deep, and bears a complex layer of microvilli in many orientations. Besides indifferent cells it contains two types of cell bodies of ciliated nerve processes. One type ends at the surface of the sensory region. The other, containing an elaborate array of smooth membranes in the perikaryon, has a process which enters the transitional region between sensory and glandular areas. In the transitional region, specialised cells with motile cilia adjoin the glandular region, and similar, but unciliated cells, containing large pigment granules scattered throughout the cytoplasm, adjoin the sensory region. The distal surface of both cell types is dissected by elefts extending 2 to 3 proximally, then widening into extensive spaces which contain cytoplasmic processes. The ciliated neurites which enter the transitional region end in the spaces at the base of the unciliated transitional cell elefts. It is suggested that the neuroepithelial cell processes, both those distributed over the sensory region and those concentrated in the transitional region, are receptors.     

Fine structure of the optic cusion in the asteroid Nepanthia belcheri

The optic cushion of Nepanthia belcheri (Perrier) is a prominent pigmented sense organ situated on the oral surface below the terminal tentacle. The distal region contains up to 170 optic cups, whilst proximally are numerous pyriform glandular cells traversed by supporting fibres. The outer margin of the optic cup is formed by alternating pigmented and photoreceptor cells. The pigmented cells contain numerous densely staining granules of scarlet pigment. The distal ends of the photoreceptors are elaborated into many long microvilli regularly arranged about a modified cilium. There is a clear circumciliary space delimiting the cilium from the microvilli.     

Histochemical and ultrastructural characterisation of mantle storage cells in the hydrothermal-vent bivalve Bathymodiolus azoricus

This study reports on two types of storage cells that are present in the mantle connective tissue of the deep-sea mussel Bathymodiolus azoricus. One type corresponds to the adipogranular cells, a kind of storage cell previously described in other bivalves. In these cells extensive regions of the cytoplasm are filled with glycogen deposits and these zones became strongly stained after histochemical (PAS) or ultrastructural detection of polysaccharides. Several lipid droplets and membrane bound granules containing homogeneous electron-dense material are also present in adipogranular cells. A second type of cell contains large lysosomes in addition to numerous lipid droplets, but lacking cytoplasmic glycogen deposits. Due to these characteristics we named them adipolysosomal cells. They can be identified in semi-thin sections stained with PAS reaction because the lysosomes are the only positively stained structures. In the connective tissue of the mantle, some cells containing many lysosomes and a few lipid droplets were also observed. These cells differ from the adipolysosomal cells mainly because they have a reduced amount of lipid reserves, and could be an initial stage in the development of adipolysosomal cells. The vesicular connective tissue cells that in other Mytilidae are specialised in glycogen storage were not detected in B. azoricus. The reserves accumulated in the two types of storage cells described in B. azoricus may be important for the survival of these hydrothermal-vent bivalves if their nutrition is affected by a temporary loss or reduction of endosymbiotic bacteria due to sulphide and/or methane shortage caused by oscillations in vent activity.     

Effects of zinc on epidermal ultrastructure in the larva of Clupea harengus

In March, 1983 changes in epidermal ultrastructure were examined in Clupea harengus L. larvae hatched from eggs incubated in four zinc concentrations (0.5 2.0, 6.0 and 12.0 ppm). In addition to the outer and inner epidermal cell types described previously, a third type of cell is present. Ultrastructurally this resembles the epidermal chloride cells of Sardinops caerulea Girard, characterised by numerous mitochondria, extensive smooth endoplasmic reticulum and a free surface exposed to the environment. These cells occur on the yolk sac, head and in the regions of the trunk just above the yolk sac. In larvae treated in 12.0 ppm zinc, the cells contain fewer mitochondria with fewer cristae than those in the controls. Smooth endoplasmic reticulum is much reduced forming nodular masses and contains granular osmiophilic inclusions. In larvae hatching from eggs previously incubated in 6.0 and 12.0 ppm zinc, the epidermal cells contain more vesicles, intracellular spaces, and swollen mitochondria and show signs of necrosis. The viability of these larvae is discussed.     

Tumor-like formations on the shells of Japanese scallops Patinopecten yessoensis (Jay)

Three types of tumor-like formations on the shell of commercial Japanese scallop Patinopecten (= Mizuhopecten) yessoensis were identified. The first type of tumor-like formation (Type I) is a brown prominent knob on the inner shell surface. This is the result of penetration of aggregations of the polychaete worms of genus Polydora into the scallop cavity usually through the upper valve of scallop and subsequent covering of their boreholes by shell calcite carbonate. The second type (Type II) is tumor-like lamination of the shell with the inclusion of organic matter between calcite layers on the inner surface of the upper and lower valves. These laminations have no outlet to the outer shell surface. The third type of scallop shell tumor-like lesion (Type III) mainly built up on the inner surface of the lower valve. It is a cone-shaped lump, which seemed to consist of aggregated coarse-grained sand. It has no outlet to the outer shell surface. Tumors of the different types are not equally distributed. Type I tumors are the most common, followed by Type II and Type III. Other kinds of tumor-like lesions on the inner shell surface are not found in the species studied. On the outer surface of scallop shell tumor-like formations were not found. The shell tumor-like lesions occurred significantly more frequently on scallops that are inhabiting muddy bottom sediments than sand. A positive relationship was found between scallop age and occurrence of shell lesions. The tumor-like formations of all types adversely influence scallops. The shell height and total, soft tissue and adductor muscle weights were lower for scallops with tumor-like formations on the shell than for healthy individuals.