DISTRIBUTION OF DIGESTIVE TUBULES AND FINE STRUCTURE OF DIGESTIVE CELLS OF APLYSIA PUNCTATA (CUVIER, 1803)

The distribution of digestive tubules of Aplysia punctatahas been studied in animals under experimental feeding conditions.Histological analysis of the digestive gland has revealed twotypes of tubules, called tubules A and B. Tubules of type Awere composed of basiphilic cells (calcium, excretory and thincells) and tubules of type B were lined by large digestive cellsand basiphilic cells. The latter occur in small groups, usuallyin the corners of the tubules. Type A tubules are involved inion metabolism and show a diphasic cycle (absorptive and reconstitutive)according to the height and the stage of calcium cells. TypeB tubules are involved in digestive processes and display atetraphasic cycle (holding, absorption, fragmentative and reconstitutive)depending upon the height and the stage of the digestive cells.The tetraphasic cycle was compared with the four categoriesof tubules in bivalves. It is proposed that digestive processesmay be continuous in digestive cells of A. punctata. (Received 16 November 1999; accepted 1 October 2000)     

The digestive gland of Viviparus ater (Mollusca, Gastropoda, Prosobranchia): an ultrastructural and histochemical study

The digestive gland of Viviparus ater was studied using histochemical and ultrastructural methods. Only one cell type was observed in the tubule epithelium of the gland. The cells are involved in an endocytotic process mediated by clathrin-coated vesicles and in the intracellular digestion of food materials (thus they can be regarded as digestive cells). The different stages of digestion and exocytotic extrusion of residual bodies into the tubule lumen were shown by electron microscopy. Very few, small mucocytes are scattered among the digestive cells. Calcium concretions, glycogen-containing cells and endocrine cells are scattered in the area of connective tissue present among the digestive tubules.     

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.     

Seasonal variation of xanthine oxidoreductase activity in the digestive gland cells of the mussel Mytilus galloprovincialis: a biochemical, histochemical and immunochemical study

The activity and the tissue distribution of the oxygen radical producing enzyme xanthine oxidoreductase (XOR) were measured in the digestive gland of the common marine mussel Mytilus galloprovincialis Lmk along an annual cycle. No xanthine oxidase (XOX) activity could be measured, the enzyme only displaying xanthine dehydrogenase (XDH) activity in all the cases. This is interpreted as a mechanism to avoid the harmful effects of the oxygen radicals that would be produced by XOX during periods following anoxic conditions at low tide. The highest XDH activities coincided with the late spring/early summer months, the activity maxima being recorded from May to July. Histochemically XOR activity was very pronounced in duct and stomach epithelial cells as well as in the surrounding connective tissue and hemolymph vessels, the activity increasing towards the summer months. These seasonal variations in XDH or XOR activities are possibly linked to hormonal changes governing the reproductive cycle and to changes in food availability. The localization of the protein in the connective tissue lining the hemolymph vessels was confirmed immunohistochemically using a polyclonal antibody against rat liver protein that cross-reacted specifically with a polypeptide of 150 kDa of molecular mass in homogenates of the digestive gland. This polypeptide was linked to cytosolic fractions isolated by differential centrifugation from mussel digestive glands. In paraffin sections the antibody labeled the digestive cells of digestive tubules, as well as the connective tissue surrounding the hemolymph vessels, gonadal follicles, digestive epithelia and certain protozoan parasites. Taken together our results suggest that in the digestive gland of bivalve molluscs XOR is involved in the metabolism of purines and in the scavenging of oxygen free radicals.     

Ovarian cycle of the captive formosan gem‐faced civets (Paguma larvata taivana)

Formosan gem‐faced civets are classified to be endemic sub‐species of Paguma larvata in Taiwan. Little about their reproductive physiology has been reported. This study was designed to characterize the ovarian activity throughout the year and define ovarian cycle length and the lengths of its component phases. Serum samples were collected for enzyme immunoassay (progesterone and estradiol) from seven captive civets twice weekly for 1 year. Meanwhile, periodic changes in external genitalia (vulva swelling) and vaginal cytology were examined and recorded. Results showed estrous cycles exhibited two types: 18‐day (18.5±1.1, n=64) and 28‐day (27.6±1.0, n=28) as shown by progesterone and estradiol fluctuations and corresponding changes in vulva morphology and vaginal cytology. Both types showed a similar 7‐day follicular phase, peaking progesterone at Day 7. The 18‐day cycle type prevails in the spring and summer whereas the 28‐day cycle type is significant in the autumn. In summary, female gem‐faced civets are polyestrous (approximately 13 cycles/year), and non‐typical seasonal breeders, with follicular phase and two distinct durations of luteal phases (diestrus) cycling throughout the year, but the frequency of ovarian cycles was remarkably gradually decreased from September to February of next year. Zoo Biol 0:1–11, 2007. © 2007 Wiley‐Liss, Inc.     

洞庭湖区社鼠消化道长度和质量的季节变化

对洞庭湖区社鼠（Niviventer confucianus）自然种群四季的消化道各器官的长度和质量进行了测定。结果表明。消化道指标季节变化明显。总体消化道含内容鲜质量、净鲜质量与干质量均具有显著的季节变化。以冬、春季较高。夏、秋季较低。消化道各器官的变化与总消化道不尽相同。其中,以胃的变化相对比较稳定。仅长度的变化达显著水平,以冬季最短,夏、秋季较长。这是动物为适应繁殖季节能量需求而增加摄食量的反应,也与夏秋季食物丰富度有关。小肠、盲肠、大肠的长度和质量指标（内容鲜质量、净鲜质量和干质量）以冬、春季较高。夏、秋季较低。这是该鼠对冬、春季低温和食物匮乏的适应性反应。总体来说。洞庭湖区社鼠为适应夏、秋季繁殖盛期能量需求增加的主要对策是增加摄食量;而为适应冬、春季低温环境和食物数量和质量减少的主要对策是增大消化道。提高消化效率。     

Variability of tubule types within the digestive glands of Mercenaria mercenaria (L.), Ostrea edulis L., and Mytilus edulis L.

The variability of the four tubule types previously recognized in the digestive glands of bivalve molluscs (viz. I, holding; II, absorptive; III, fragmenting; and IV, reconstituting) was investigated using photomicrographs of the digestive glands of subtidal Mercenaria mercenaria (L.), low-intertidal Ostrea edulis L., and mid-intertidal Mytilus edulis L. The clustering of similar tubule types around common secondary ducts was observed both histologically and by statistical analysis. A ratio type estimator was used in consideration of this clustering to determine proportions and variances of each tubule type. Intra-animal variances of Type II tubules were approximately the same for each species, ranging from 0.0419–0.0570. Inter-animal variances were also similar (0.0060–0.0140), but only 10–25% of the intraanimal values. Sampling schemes involving large numbers of animals but few photomicrographs of each digestive gland would minimize overall variance. Because of high variability, the necessity of taking numerical data and of using proper statistical analysis in all studies based on the changing morphological appearance of the bivalve digestive gland is stressed.     

Seasonal variations in biochemical composition during the reproductive cycle of the veined rapa whelk Rapana venosa (Valenciennes, 1846) from the northern coast of China

Seasonal variations in the biochemical composition of Rapana venosa in relation to reproductive cycle and environment on the northern coast of China were investigated from March 2012 to February 2013. The results indicated that R. venosa has an annual reproductive cycle with synchronized gonad development in both females and males. Gametogenesis was initiated in September and gametes developed slowly during the winter, followed by rapid gonad development during spring and summer. Most individuals from this study were sexually mature between May and June, and gamete release occurred mainly between May and August. The peak of spawning was found in July and the recovery of the gonad was observed between August and November. The key biochemical components including glycogen, protein and lipid were analysed in four tissues, specifically the gonad, digestive gland, mantle and foot. The declining glycogen content in the gonad, digestive gland and mantle during maturation suggested that glycogen was consumed during the development of the gonad. Lipids and protein can be stored in the digestive gland and used during the winter in a period of food shortage. The protein and lipid contents in the ovaries increased during gonad development, which suggested that the protein and lipid had been accumulated as vitellin in oocytes.     

Morphological, micromorphological and histochemical studies on the parotid salivary glands of the one-humped camel (Camelus dromedarius).

The morphology, blood and nerve supply of the parotid salivary glands of the one-humped camel were studied in detail. The intraglandular portion of the duct system was also examined. The histological and histochemical studies showed that the parotid salivary glands of the camel are of the tubuloacinar type and are serumocoid in nature. The secretory acini and tubules show themselves in 3 different forms according to the different phases of their secretory cycle. The duct system of the gland contains goblet cells between its lining epithelium. The intercalated ducts show ampullation followed by narrowing that help in mixing the secretion. Intraepithelial glands are found in the terminal part of the parotid duct.     

Seasonal Morphological Changes in the Intestinal Digestive Epithelium of the Mussel Crenomytilus grayanus

Seasonal morphological changes in the intestinal digestive epithelium of the mussel Crenomytilus grayanus (Dunker) were studied. No changes in the cellular composition of the lining epithelium of the intestine were revealed during the annual cycle. Cyclic morphofunctional changes, including reduction of the height of the epithelium in summer and its hypertrophy in winter, increase in the number and size of the nucleoli, etc., were shown to occur.     

鳜鱼消化道黏液细胞和6种酶的组织化学定位

采用阿利新蓝-过碘酸雪夫氏(AB-PAS)染色和酶组织化学方法对鳜鱼消化道各部位黏液细胞和6种酶的分布与定位进行了研究。结果显示,黏液细胞可为分为4种类型,食道黏液细胞多数为Ⅲ型和Ⅳ型,未见Ⅰ型和Ⅱ型;胃贲门和胃幽门黏膜上皮仅有Ⅰ型黏液细胞;胃体黏膜上皮则以Ⅲ型细胞为主;幽门盲囊中主要为Ⅱ型细胞;前肠和中肠中Ⅳ型黏液细胞最多,Ⅰ型最少;后肠黏液细胞则以Ⅳ型和Ⅱ型为主。酸性磷酸酶(ACP)主要分布于幽门盲囊和前肠的黏膜上皮;碱性磷酸酶(ALP)主要分布于食道、幽门盲囊和整个肠道黏膜上皮;非特异性酯酶(NSE)主要分布于胃幽门、中肠和后肠黏膜上皮;过氧化物酶(POX)在胃幽门黏膜上皮中活性较高;琥珀酸脱氢酶(SDH)主要分布于胃腺中;腺苷三磷酸酶(ATPase)在消化道各部位均有较多分布。鳜鱼消化道黏液细胞和酶的分布型与其它动物有相似之处,也有其一定的特异性,与消化道不同部位的消化吸收机能相适应。     

The tidal rhythm of feeding and digestion in the pacific oyster, Crassostrea gigas (Thunberg)

A study has been made of the processes of extra- and intracellular digestion in the Pacific oyster, Crassostrea gigas (Thunberg) over two 24-h cycles in winter and summer.The results show that the digestive processes are discontinuous and related to the tidal cycle. Variations in tidal height resulting from a diurnal inequality of the tide affect both the relative dissolution of the crystalline style and the relative lengths of the constituent phases of the intracellular digestive process in the digestive diverticula. On a seasonal basis the style is present for a greater length of time in winter and, conversely, remains dissolved longer in summer. A seasonal variation in the structure of the digestive tubules has also been found.The results confirm conclusions reached earlier that the processes of extracellular digestion in the stomach and intracellular digestion in the digestive diverticula of intertidal bivalves are both discontinuous, alternate, and irrevocably interrelated since breakdown of the digestive cells of the digestive diverticula following intracellular digestion results in the dissolution of the crystalline style. The arrival of food in the stomach has a minimal effect upon the style. Moreover, the cytological structure of the digestive diverticula of C. gigas undergoes a series of synchronized changes related to the tidal cycle.     

Seasonal flexibility in organ size in the Andean lizard Liolaemus moradoensis

The understanding of animal functioning in fluctuating environments is a major goal of physiological and evolutionary ecology. In temperate terrestrial habitats, one of the most pervasive changes in environmental conditions is that associated with the seasonal change along the year. In this study, we describe the pattern of seasonal variation in the size of nine internal organs in the lizard Liolaemus moradoensis from the Andes Mountains of Central Chile. We observed that the size of digestive organs was greater during summer in comparison to other seasons. Dry masses of liver and fat bodies reached maximum values during summer and minimum during spring. We suspect that lowest spring values are related with build‐up costs of energetically expensive organs (e.g., digestive, muscle mass) at the end of the hibernation period. Dry mass of the heart and lungs did not show a clear pattern of variation, suggesting that cardiac and pulmonary performance were maintained throughout the year. The dry mass of kidneys was greater during winter than during summer, a result observed in other hibernating lizards but for which there is no clear explanation. Finally, the dry mass of testes showed a maximum value during autumn and a progressive reduction toward summer, indicating that reproduction occurs during autumn. When represented in a bivariate space, acquisition (digestive), distribution (heart, lungs and kidneys), storage (liver and fat bodies), and expenditure (testes) organs generate four clusters. In general terms, observed seasonal pattern of change in organ size is in agreement with those reported for other lizard species that inhabit highly fluctuating environments. J. Morphol., 2010. © 2010 Wiley‐Liss, Inc.     

粉尘螨消化系统的形态学观察

光镜下观察了粉尘螨Dermatophagoides farinae消化系统结构,其组成包括：口前腔、前肠、中肠、后肠、肛门和唾液腺。口前腔由颚体围绕而成;前肠包括一个肌肉的咽和食道,食道从脑中穿过;中肠分为前中肠（包括一对盲肠）和后中肠,中肠的上皮细胞呈现多种形态; 后肠包括相对大的结肠和狭窄的直肠;消化腺为不规则形,位于脑前方。本文阐述了消化道的分支情况、显微结构及细胞形态。     

The effects of tidal currents on the rhythm of feeding and digestion in Pecten maximus L.

The orientation of individuals in two populations of Pecten maximus L., from the west coast of Ireland, shows that they have a marked preference to face directly into a tidal flow. In both localities examined there was a reversal of tides and the members of the populations were divided equally for flood and ebb tides. Twenty-four hour in situ studies of the animals were made and at all stages of the tide individuals facing either due east or west were observed. A cyclical feeding pattern imposed by the reversal of tidal flow is proposed.The pH of various parts of the digestive tract was investigated and showed a wide range of values. The most acid region was that of the stomach. The variations in pH of all of the regions of the gut examined throughout a 24-h period closely followed the pattern of the tidal cycle.Histological analysis of the stomach and digestive diverticula of representative samples of scallops taken at regular intervals over the 24-h periods clearly indicated a diphasic pattern of digestion within the tubules of the digestive diverticula. A close correlation between the phases of intracellular digestion, the pH variations in different regions of the gut, and the tidal cycle indicate distinct feeding cycles in Pecten. Those scallops facing into the ebb current show the same diphasic patterns as those individuals facing the flood current, but are 6 h out of phase. The cycle is considered as a duplication of a diphasic feeding pattern. The tubules themselves undergo a digestive process similar to that in Lasaea rubra (Montagu). The digestive cells phagocytose food material, begin intracellular digestion, and increase in size until they obscure the lumina. The dispersal of waste material and residual bodies is accomplished dramatically by a dehiscence of the tubule cells together with a loss of both digestive and crypt cells. New tubules are regenerated from the apices of those tubules breaking down. In any section of the diverticula tubules in two different conditions are found. The cycle of digestion takes 24 h and in order to facilitate feeding at each 12-h tidal cycle the tubules are equally divided into two phases with one 12 h behind the other.     

Ectal mandibular gland in Polistes dominulus (Christ) (Hymenoptera, vespidae): ultrastructural modifications over the secretory cycle

An ultrastructural study was carried out on the secretory activity of the ectal mandibular gland in the wasp Polistes dominulus (foundress and worker females as well as males). Secretory activity in foundresses proceeds slowly during hibernation and early spring, becoming prominent in late spring and then falling sharply during the summer. This sequential pattern of ultrastructural modifications follows a functional, annual cycle. However, by comparing the subcellular changes in the gland with colonial development, it appears that secretory activity fits in with the specie's social cycle rather than merely following the seasons. The highest levels of secretory activity correspond to the early, critical breeding phases, while activity slows down with an increase in colony protection, based on both primary (passive) and secondary (active) defenses, with the emergence of the workers. These correlations suggest that the ectal mandibular gland secretory product in P. dominulus is involved in chemical nest defense.     

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.     

Characterization of intracytoplasmic prokaryote infections in Dreissena sp. (Bivalvia: Dreissenidae)

This study characterizes intracytoplasmic infections with prokaryote microorganisms in Dreissena sp. (near Dreissena polymorpha) from northeastern Greece and represents the first report of such infections in freshwater bivalves. Light microscope observations of stained tissues revealed basophilic, cytoplasmic inclusion bodies in 87.5% (28/32) of the mussels sectioned. Inclusions in epithelial cells and connective tissues were noted, respectively, in 34.4 and 71.9% of the sample, with 5 mussels (15.6%) having both tissue types infected. Epithelial cell infections were observed in histological sections only in digestive gland tubules and ducts; within tubules, inclusions were present more often in secretory than digestive cells. Connective tissue infections, however, were systemic; among the 32 mussels sectioned, inclusions were found in the gills (65.6%), foot (12.5%), mantle (9.4%), labial palps (6.3%), digestive gland (6.3%), stomach (6.3%), and gonads (3.1%). Cytoplasmic inclusions (maximum dimension, 138 microm) were prominent enough in the gills to be visible in 17.0% of the 247 mussels dissected. Ultrastructurally, prokaryote cells in gill connective tissues were clearly characteristic of Chlamydiales-like organisms, with each intracytoplasmic inclusion containing a loosely packed mixture of elementary, reticulate, intermediate bodies, and blebs. Prokaryote colonies in digestive gland epithelial cells exclusively contained 1 of 4 morphological cell types and were considered Rickettsiales-like. Hexagonal, virus-like particles were present in the cytoplasm of the largest of these Rickettsiales-like prokaryotes. Although host stress was evident from localized cell necrosis and dense hemocyte infiltration, overall infection was fairly benign, with no major, adverse impact on body condition evident among sectioned or dissected mussels. A possible negative effect was partial constriction of gill water tubes, but at the infection intensity observed (typical range 1 to 7 inclusion bodies per section), significant interference with respiration and other metabolic functions of the gills was highly unlikely.     

The pineal gland and seasonal reproductive adjustments

The pineal gland seems to play a major role in controlling and synchronizing circannual reproductive cycles in some mammals. The following scheme is based primarily on experimental evidence compiled using the golden hamster. However, it is probably applicable in one form or another to a number of long day breeding species. When hamsters are kept under natural photoperiodic conditions they exhibit a period of infertility followed by a period of fertility. The entire cycle encompasses approximately one year. The cycle has been divided into 4 distinctive phases: the inhibition phase, the sexually quiescent phase, the restoration phase, and the sexually active phase. During the inhibition phase the decreasing photoperiods in the fall of the year cause activation of the pineal gland and, as a consequence, gonadal regression. The sexually quiescent phase requires an intact pineal gland to maintain the gonads in a non-functional state. The restoration phase, which occurs in the spring of the year, allows the gonads to become recrudescent. This phase of the cycle seems to be light independent. The sexually active phase extends from spring until fall. During this phase the hypothalamo-pituitary-gonadal axis seems to be refractory to inhibition by the pineal gland. Some light is required during the summer months to interrupt the refractory period.