Changes in the digestive gland of the loliginid squid Sepioteuthis lessoniana (Lesson 1830) associated with feeding

Changes associated with feeding in the histological and cytological structure of the digestive gland of the loliginid squid Sepioteuthis lessoniana were examined, along with the nature of both the intracellular and extracellular enzymes produced by the gland. The timing of the release of the extracellular enzymes during the digestive cycle was also determined using a quantitative experimental program. Like that of all coleoid cephalopods, the digestive gland was characterised by one type of cell with several functional stages. As is the case for other loliginid squids, however, the digestive cells did not contain the large enzyme-carrying boules that characterise the digestive glands of most cephalopods. Instead, smaller secretory granules were found in the digestive cells and these may be the enzyme carriers. The prominent rough endoplasmic reticulum, large mitochondria and active Golgi complexes present in the digestive cells are characteristic of cephalopods and indicate a high metabolic activity. Like that of other cephalopods, endocytotic absorption of nutrients and intracellular digestion occurs in the digestive gland of this squid. From quantitative and qualitative examinations of structural changes in the digestive gland of S. lessoniana after feeding, a schedule of its function during the course of digestion was proposed. This indicated that digestion was very rapid, being completed in as little as 4 h in S. lessoniana. Extracellular digestive enzymes were only released after the first hour following feeding, which implies that they are stored in the stomach between meals to increase digestive efficiency.     

Microstructural and histochemical advances on the digestive gland of the common cuttlefish,Sepia officinalis L.

The cephalopod digestive gland is a complex organ that, although analogous to the vertebrate liver, has additional functions, with special (albeit not exclusive) note on its active role in digestion. Although the structure of the digestive cell and its main constituents are well known (among which “boules” and brown bodies are distinctive features), histological details of other cell types and the general structure of the digestive gland need still further research. By a thorough combination of histological and histochemical techniques, it is shown that the digestive gland diverticula of the common cuttlefish (Sepia officinalis L.) are comprised of three essential cell types: digestive, basal and excretory. Basal (“pyramidal”) cells are multi-functional, being responsible for cell replacement and detoxification, mainly through the production of calcic spherulae containing metals like copper and lead in a complex organic matrix of proteins and ribonucleins. Since copper- and lead-positive spherulae were almost absent from other cell types and lumen of the tubules, it appears that controlled bioaccumulation of these metals, rather than excretion, is the main detoxification mechanism. The results show that the organ is crossed by an intricate network of blood vessels, especially arteries and arterioles, whose contents share histochemical properties with a particular set of “boules” that are shed into the lumen of diverticula for elimination, suggesting that the organ actively removes unwanted metabolites from the haemolymph. Conversely, the rarer excretory cells appear to be specialized in the elimination of salts. Although the exact nature of many excretory and secretory products, as the metabolic pathways that originate them, remain elusive, the findings suggest an intricate interaction between the different cell types and between these and the surrounding media: haemolymph and digestive tract.     

Morphofunctional characterization and ploidy levels of cells in the bivalve digestive gland, with special reference to somatic polyploidy

This study investigates the histological organization and ploidy levels of the digestive gland cells in 29 species of marine, brackish water, and freshwater bivalves belonging to 5 subclasses. In all species studied, the digestive gland epithelium consists of two types of differentiated cells: digestive and basophilic. The nuclei of digestive cells contain the diploid quantity of DNA. Basophilic (secretory) cells often remain diploid also; however, in a number of species all or some of the cells showed an increase in the quantity of DNA per nucleus up to 4c. Tetraploidy of basophilic cells in several species of the subclass Anomalodesmata seems to be due to carnivory. In other species, no apparent correlation was found between selective polyploidy of basophilic cells and environmental conditions or biology traits of the bivalves. Additionally, there was no relationship between the occurrence of polyploid cells and the lifespan of the investigated species. In the bivalve mollusks, somatic polyploidy appears to be an adaptation; it is neither a tissue growth strategy nor a component of the cytodifferentiation program.     

Fine structure and absorption of ferritin in the digestive organs of Loligo vulgaris and L. Forbesi (Cephalopoda,Teuthoidea)

The digestive organs possibly involved in food absorption in Loligo vulgaris and L. forbesi are the caecum, the intestine, the digestive gland, and the digestive duct appendages. The histology and the fine structure showed that the ciliated organ, the caecal sac, and the intestine are lined with a ciliated epithelium. The ciliary rootlets are particularly well developed in the ciliated organ, apparently in relation to its function of particle collection. Mucous cells are present in the ciliated organ and the intestine. Histologically, the digestive gland appears rather different from that of other cephalopods. However, the fine structure of individual types of squid digestive cell is actually similar to that of comparable organs in other species, and the squid cells undergo the same stages of activity. Digestive cells have a brush border of microvilli, and numerous vacuoles, which sometimes contain “brown bodies.” However, no “boules” (conspicuous protein inclusions of digestive cells in other species) could be identified in their cytoplasm; instead only secretory granules are present. In the digestive duct appendages, numerous membrane infoldings associated with mitochondria are characteristic features of the epithelial cells in all cephalopods. Two unusual features were observed in Loligo: first, the large size of the lipid inclusions in the digestive gland, in the caecal sac, and in the digestive duct appendages; and second, the large number of conspicuous mitochondria with well-developed tubular cristae. When injected into the caecal sac, ferritin molecules can reach the digestive gland and the digestive duct appendages via the digestive ducts, and they are taken up by endocytosis in the digestive cells. Thus, it appears that the digestive gland of Loligo can act as an absorptive organ as it does in other cephalopods.     

An examination of the role of the digestive gland of two loliginid squids,with respect to lipid: storage or excretion?

The role of the digestive gland, with respect to non-structural lipid, was examined using proximal analysis, histochemistry and quantitative histological techniques in the tropical loliginid squids Sepioteuthis lessoniana (Lesson) and Photololigo sp. The digestive gland of both species was characterized by large and numerous lipid droplets in the apical portion of the digestive cells and very few in the basal portion. The apical lipid droplets were released into the lumen of the gland and subsequently rapidly removed. Despite the numerous large apical lipid droplets, the lipid concentration in the digestive glands of S. lessoniana and Photololigo sp. was lower than that reported for most squid species. There was no relationship between lipid concentration and stage of digestion, suggesting that lipid is not stored in the gland after a meal. There was also no relationship between lipid concentration and the sex of an individual or stage of reproductive maturity, suggesting that these squids are not storing lipid in the digestive gland for use in fuelling reproductive maturation or providing an energy source for oocytes. I believe this study is the first to combine proximal analysis and quantitative histological techniques to examine the role of the squid digestive gland with respect to non-structural lipids. The results indicate that the digestive gland of these tropical loliginid squids is excreting, not storing, excess dietary lipid.     

Absorption of ferritin by cells of the digestive gland in Nassarius tegula (Gastropoda : Prosobranchia)

Within 12 min after the prosobranch snail, Nassarius, begins feeding on ferritin-labeled food, ferritin reaches the lumen of the digestive gland and is absorbed by the digestive cells lining the gland. Within the digestive cells, the ferritin is present in coated pinocytotic vesicles, in microvesicles and in macrovesicles. It is probable that ferritin (and components of the food as well) progresses rapidly in order from the gland lumen to the pinocytotic vesicles to the microvesicles to the macrovesicles. The macro vesicles are presumably an important site of intracellular digestion.     

Light and electron microscope localization of beta-glucuronidase activity in the stomach and digestive gland of the marine gastropod Littorina littorea

Summary An azo dye technique was used to investigate localization of the acid hydrolase,-glucuronidase, at light and electron microscope level in the stomach and digestive gland of the marine periwinkleLittorina littorea. Activity for-glucuronidase was located principally within digestive cells of the digestive gland and also associated with the microvillous border and epithelial cells lining the stomach. At the light microscope level all digestive tubules showed activity which appeared essentially restricted to the large heterolysosomes of the digestive cells. However not all digestive cells showed activity. In the electron microscope, reaction product was apparent in all types of macrovesicle in the digestive cells although not all stained positively. Heterophagosomes typically showed reaction product around their periphery or associated with the electron opaque contents. Activity was commonly seen around the apical edge of heterolysosomes where merging of heterophagosomes into heterolysosomes was apparent. Reaction product was commonly located within small electron lucent vesicles which lined the internal membrane of the heterolysosomes but sometimes also associated with flocculent, electron opaque contents. In the stomach dense clusters of reaction product were visible in lysosomes in the basal region of the epithelial cells and in the large granular inclusions of the secretory cells.     

Histopathology of the digestive gland of the bivalve mollusk Crenomytilus grayanus (Dunker, 1853) from southwestern Peter the Great Bay, Sea of Japan

The histomorphology of the digestive gland of the bivalve mollusk Crenomytilus grayanus from Sivuchya Bay, which is located in the southwest of Peter the Great Bay and subjected to the effect of polluted waters of Tumannaya River, was studied. Pathological changes of the digestive tubules, channels, and connective tissue of the gland were recorded in all the mussels studied. The epithelium of the tubules and channels was characteristic with erosive disturbances and by heavy vacuolization of digestive cells; connective tissue of the gland was specified by cells with lipofuscin (granulocytomes) and by foci of cells necrosis and lysis. Nervous fibers running in the gland were swollen in some mollusks. Strongly basophilic spherical formations, presumably one of the development stages of a parasitic plasmodium, were found in the granulocytomes and among vesicular cells of connective tissue of all the mussels. It was concluded that pathological changes in digestive gland of Gray’s mussel might be caused by chronic pollution of the bay and by parasitic invasion.     

Fatty acid profile of the digestive gland and mantle in the bivalve Macoma balthica

• 1.1. Digestive gland and mantle fatty acids were studied in spring and summer in the bivalve Macoma balthica off the southern coast of Finland. The presence of lipids was also examined histochemically in various clam tissues.
• 2.2. the neutral lipid content of the digestive gland increased ca 4.5-fold during the annual growth period.
• 3.3. Neutral lipid fatty acids of the digestive gland, of which palmitoleic, eicosapentaenoic and palmitic acids were predominant, were clearly distinguished from phospho- and glycolipid fatty acids.
• 4.4. The degree of unsaturation of phospholipid fatty acids was higher in the cold season both in the digestive gland and mantle, mainly due to the titer of eicosapentaenoic acid.

     

The digestive gland of the Southern Dumpling Squid (Euprymna tasmanica): structure and function

The cephalopod digestive gland plays an important role in the efficient assimilation of nutrients and therefore the fast growth of the animal. The histological and enzymatic structure of Euprymna tasmanica was studied and used in this experiment to determine the dynamics of the gland in response to feeding. The major roles of the digestive gland were secretion of digestive enzymes in spherical inclusions (boules) and excretion of metabolic wastes in brown body vacuoles. High levels of trypsin, chymotrypsin and α-amylase, low levels of α-glucosidase and negligible carboxypeptidase activity were produced by the gland. There was no evidence of secretion of digestive enzymes in other organs of the digestive tract. Within 60 min of a feeding event, the gland produced increasing numbers of boules to replace those lost from the stomach during the feeding event. Initially, small boules were seen in the digestive cells, they increased in size until they are released into the lumen of the gland where they are transported to the stomach. There was no evidence of an increase in activity of digestive enzymes following a feeding event, despite structural changes in the gland. However, there was large variation among individuals in the level of digestive enzyme activity. A negative correlation between boule and brown body vacuole density suggested that the large variation in enzyme activity may be due to the digestive gland alternating between enzyme production and excretion.     

Histochemical changes of carbohydrate and protein contents in the digestive gland cells of the land snail Monacha cartusiana following starvation

The present study was designed to investigate histochemically the detection of carbohydrate and protein in the normally feeding snails and after 15 and 30 days of starvation. Generally, abundant carbohydrate and protein materials were detected in the component cells of the digestive gland of normally feeding snails. The results of this investigation revealed a pronounced decline of carbohydrates in the digestive gland cells of Monacha cartusiana snails after starvation. Severe decline in carbohydrate content was observed especially after 30 days of starvation. Moreover, protein inclusions have exhibited a week stainability in the digestive gland cells of these snails as a consequence of starvation.     

Nitroxidergic elements in the digestive system of Mactra chinensis and Spisula sachalinensis (Mollusca: Bivalvia: Mactridae)

Localization and morphology of NO-ergic elements in the digestive system of bivalve molluscs Mactra chinensis and Spisula sachalinensis were studied using histochemical technique [1] for detection of NADPH-diaphorase (EC 1.6.99.1) [1]. The NO-producing elements were revealed in all parts of the digestive system of the studied animals. NADPH-diaphorase was found in cells of several morphological types as well as in nerve plexuses. The most abundant in the digestive tract parts of the studied molluscs were intraepithelial nerve cells of the “open” type, whose thin apical process is directed towards the gut lumen. Subepithelial NO-ergic neurons were revealed in stomach and crystalline style sac of Mactra chinensis. Besides, diformazan granules are present in brush-border epitheliocytes of the major and secondary ducts of the digestive gland as well as in cells of digestive tubules of this gland. All studied parts were found to contain basiepithelial and subepithelial NO-ergic nerve fibers forming networks of various densities from, most commonly, loose to dense plexuses particularly developed in labia, esophagus, and gut of the studied molluscs.     

Regeneration of radiation-damaged digestive tissues in juvenile Pacific oysters (Crassostrea gigas)

Juvenile Pacific oysters, Crassostrea gigas, were irradiated with 16 and 40 krad and their tissues examined histologically. Degenerative syndromes and tissue regeneration processes were determined for the stomach, gut, collecting ducts, and digestive tubules. Following degeneration, tissue regeneration was observed in the digestive tissues of most oysters exposed to 16 krad and in a limited number exposed to 40 krad. Regeneration was first observed in the digestive tubules and subsequently in the stomach, gut, and collecting ducts. Cellular repopulation of the digestive tubules involved epithelialization with large, undifferentiated crypt cells which then differentiated into functional secretory and absorptive cells. Regeneration in the stomach, gut, and collecting ducts was initiated by proliferative islands of small basophilic cells. Mitotic division of those cells and their subsequent differentiation into functional epithelial cells resulted in the rapid restoration and apparent recovery of the affected tissues. The results of these studies indicate that radioresistance of juvenile C. gigas may in part be due to the remarkably efficient regenerative mechanisms involved in replacing injured or lost digestive tissues.     

Three digestive movements in<Emphasis Type="Italic"> Hydra</Emphasis> regulated by the diffuse nerve net in the body column

The mammalian digestive tract undergoes various digestive movements such as peristalsis and segmentation movement. How those digestive movements and the underlying mechanisms appeared in evolution remains unraveled. A widely accepted view has been that, early in evolution, the digestive process was static based upon diffusion, and later it became dynamic involving digestive movements. Here, we report digestive movements which occur in Hydra, a member of the phylum Cnidaria. We find that the body column of Hydra undergoes a series of movements when fed with Artemia. Comparison of the movements to those in mammals showed similarities in appearance to esophageal reflex, segmentation movement, and defecation reflex. When nerve cells were eliminated, polyps showed only a weak segmentation movement, demonstrating that the diffuse nerve net in the body column of Hydra primarily regulates the movements just as the netlike enteric nervous system does in mammals. Elimination of both secretory gland cells and nerve cells resulted in the complete loss of movement, suggesting that the gland cells are involved in the weak movement. Overall, these observations suggest that the digestive process in Hydra is dynamic and that the diffuse nerve net regulates the digestive movements as a primitive form of enteric nervous system.     

Glutathione enzymes,glutathione content and t-butyl hydroperoxide induced lipid peroxidation in the gill and digestive gland of the estuarine clam,Rangia cuneata

1. Reduced glutathione (GSH), glutathione reductase (GSSG-reductase) and glutathione peroxidase (GSH-peroxidase) activities were measured in the gill and digestive gland of Rangia cuneata.2. Substantial GSH concentrations were found in both gill (820 ± 80 nmole/g tissue) and digestive gland (930 ± 130 nmole/g tissue). The digestive gland exhibited 2.5-fold greater GSSG-reductase activities and 0.5-fold lower GSH-peroxidase activities relative to the gill.3. In vivo exposure to t-butyl hydroperoxide (BHP) elicited a dose-dependent increase (P < 0.05) in lipid peroxidation in both tissues. Lipid peroxidation occurred earlier and to a greater extent in the digestive gland versus the gill. GSH concentrations in both tissues were unaffected by BHP exposure.4. The study results indicate that gill and digestive gland differ in susceptibility to BHP induced oxidative damage, and the difference is accounted for by differences in tissue GSH metabolism.     

Cytological and enzyme-histochemical investigations on the digestive organs of Nautilus pompilius (Cephalopoda, Tetrabranchiata)

The foregut, stomach, caecum, midgut, and rectum of the digestive tract of Nautilus pompilius L.were investigated with ultrastructural and enzyme-cytological methods. Three different cell types were identified within the lamina epithelialis mucosae: main cells, goblet cells, and cells with secretory granules. The main cell type is the epithelial cell with microvilli, a basal nucleus surrounded by dictyosomes, rough endoplasmic reticulum, mitochondria, and electron-dense granules identified as lysosomes in the apical part of the cell. In the caecum this cell type contains endosymbiotic bacteria. The presence of endocytotic vesicles and the storage of lipids in the caecum indicate that this organ is involved in the process of absorption. In the caecum and the longitudinal groove of the rectum the main cells are, in addition, ciliated, facilitating the transport of food particles and faeces. Two types of goblet cells are found in all organs except in the stomach, forming a gliding path for food particles and protecting the epithelium. In the foregut and rectum, cells with electron-dense granules were recognized as the third type. The conspicuous secretory cells of the rectum represent a delimited rectal gland; its possible biological function is discussed. The tunica muscularis in all organs of the digestive tract consists of obliquely striated muscle cells innervated by axons containing transparent, osmiophilic and dense-cored vesicles. Positive reactions for acid and alkaline phosphatase, monoamine oxidase, β-glucuronidase, and trypsin- and chymotrypsin-like enzymes are localized in the lamina epithelialis mucosae.     

The ultrastructure of the tegument and the digestive caeca of in vitro cultured metacercariae of Fasciola hepatica

Davies C. 1978. The ultrastructure of the tegument and digestive caeca of in vitro cultured metacercariae of Fasciola hepatica. International Journal for Parasitology8: 197–206. The ultrastructure of the tegument and digestive caeca of metacercariae of Fasciola hepatica grown in vitro in two different media is described and compared with the development of these two systems during maturation in vivo. Although the tegument of metacercariae grown in Medium RC showed no development, that of flukes cultured in Medium CS began to produce T-1 and T-2 granules typical of the liver phase of development in vivo. The gastrodermal cells showed some degree of conversion to an adult-like morphology in vitro with the production of typical secretory granules, a limited amount of orientation of the GER and the development of junctional complexes with adjacent parenchyma cells—this was particularly evident in flukes from Medium CS. The growth achieved in each of the culture media is correlated to the degree of development of the tegument and the digestive caeca.     

Comparative study of the sterol composition of the digestive gland and the gonad of Sepia officinalis L. (mollusca,cephalopoda)

• 1.1. The sterol composition of the digestive gland and the gonad of Sepia officinalis L. was investigated by GC and GC-MS.
• 2.2. The same sterols were recognized in both organs, cholesterol being the major component of the sterol mixtures. However, quantitative differences appeared between the sterol composition of the digestive gland and the gonad.
• 3.3. The sterol mixtures of the digestive gland and the gonad of immature and mature females and males of various origins were compared. Quantitative changes in the sterol composition of the gonad were related to sexual maturity whereas the sterol composition of the digestive gland appeared linked to the diet.

     

The functional morphology of the alimentary tract of barnacles (Cirripedia: Thoracica)

The alimentary tract of barnacles is made up of cuticle-lined foregut and hindgut with an intervening U-shaped midgut associated anteriorly with a pair of pancreatic glands and perhaps midgut caeca. Epithelial salivary glands secrete acid mucopolysaccharide, glycoprotein or both. Cells of all the midgut regions are capable of absorption which is carried out mainly by the anterior midgut and caeca. Midgut cells of Balanus balanoides (L.) show a seasonal variation in the distribution of intracellular lipid droplets. Midgut cells rest on an elastic basal lamina and secrete a peritrophic membrane which contains mucopolysaccharide and protein. Cells of the stratum perintestinale connect with the midgut epithelial cells via cell processes which probably translocate absorbed materials. Glycoprotein globules and lipid droplets accumulate in the body parenchyma of B. balanoides and are transported to the ovaries to form yolk (glycolipovitellin). The pancreatic gland cells of all barnacles are active secretory cells secreting proteinaceous material (probably digestive enzymes).     

Effects of vertebrate growth factors on digestive gland cells from the mollusc Pecten maximus L.: an in vitro study

In relation with the digestive cycle, the digestive gland cells of bivalve molluscs undergo a sequence of cytological changes which is controlled by external and internal effectors such as putative gastrointestinal hormones and growth differentiation factors. A tissue dissociation method was developed to investigate the in vitro effect of the vertebrate growth and differentiation factors: insulin, insulin growth factor I (IGF-I), basic fibroblast growth factor (bFGF) and epidermal growth factor (EGF) on the digestive gland cells of the scallop Pecten maximus. All these vertebrate peptides induced a dose-dependent increased incorporation of ³H-leucine and ¹⁴C-uridine in whole digestive gland cell suspensions. However, after Percoll density gradient purification of the digestive cells, only stem and undifferentiated enriched cell fractions were responsive to the different peptides. In addition, insulin and IGF-I, but not EGF and bFGF, stimulated ³H-leucine incorporation in control dispersed mantle edge cells. These results suggest that insulin-related peptides could work as general growth promoting factors in molluscs. On the other hand, EGF and bFGF, or at least their molluscan counterparts, may be efficient growth differentiation factors in the regenerative processes occurring in the digestive gland of molluscs. Accepted: 26 September 1997