Studies on the host/parasite interface during the development of a pentastomid arthropod parasite in rodent intermediate hosts, with observations on protective surface membranes

The changing structure of the cuticle of the arthropod pentastomid parasite Porocephalus crotali, during growth to the infective stage in mouse and rattlesnake hosts, is described. The outermost cuticulin layer of the cuticle in instars II-VI is elevated to form a dense mat of epicuticular hairs. Since the VI larval cuticle is retained by the infective (VII) nymph as a protective sheath, effectively all stages in mice present a hairy surface to the host and this may constitute a physical barrier to inflammatory cells. The entire surface is overlain by a triple-track 'unit' membrane whose biophysical properties resemble those of a conventional plasma membrane, and there is evidence to suggest that this membrane is susceptible to immune attack. Under natural circumstances, epicuticular hairs entrap secretion, delivered to the cuticle via innumerable minute ducts which communicate with tegumental secretory cells termed subparietal cells (SPC). SPC synthesize lamellate droplets which unfold on the cuticle to constitute a layer of protective polymorphic vesicles. By contrast, infective nymphs in snakes possess a smooth cuticle and SPC membranous secretion is stacked over the entire surface, in sheets up to 20 deep. The function of the lipid and protein components of SPC secretion is discussed.     

Fine structural aspects of secretory processes in a pentastomid arthropod parasite in its mouse and rattlesnake hosts

The histology and development of three extensive glands in the porocephalid pentastomid Porocephalus crotali is described by light and electron microscopy, during growth of the parasite to an infective stage in the tissues of mouse; the infective stage in rattlesnake definitive hosts is also included. These glands elaborate excretory/secretory components which are channelled, via chitin-lined efferent ductules, on to the parasite cuticle. Hook and frontal glands are relatively compact, and within each gland ductules serving individual secretory lobules collect into common ducts which discharge over each of the four hooks, or at the anterior margin of the cephalothorax respectively. Subparietal gland cell lobules, composed of two large and two small secretory cells, are distributed under the cuticle and each is served by a single efferent ductule; these erupt over the entire cuticle. The large cells in subparietal glands secrete lamellate droplets which coat the cuticle with thin layers. Identical cells are found in hook and frontal glands, in addition to to three morphologically distinct types of protein secretory cell. Preliminary data on the composition and immunological properties of the various secretory products are presented.     

Further evidence for the protective role of sub-parietal cell membranous secretory product on the cuticle of a pentastomid arthropod parasite developing in its rodent intermediate host

The pentastomid parasite Porocephalus crotali, develops to an infective stage within a granulomatous lesion in the tissues of rodent intermediate hosts. A conspicuous layer of sub-parietal cell (SPC) secretory product, which coats the intermoult cuticle up to a depth of 12 microns, is described. Around the first five nymphal instars this material consists of an amorphous matrix with distinctive electron-lucid lacunae, but that around later instars (six and seven), while retaining much of the original morphology, possesses a significant membranous component. Host effector cells, most notably eosinophils and macrophage/epithelioid cells, are frequently completely enveloped by SPC secretion but invariably appear unreactive to it. Host cells may penetrate to the outermost layer of the epicuticle but again but again cytotoxic activity is absent. During ecdysis, effector cells are recruited to the intercuticular space where widespread degranulation is evident. Some of this is specifically directed against the underside of the cast cuticle, but not against the newly exposed cuticle. Protracted degranulation eventually reduces the cast cuticle to fragments which are endocytosed by giant cells. 1 cm long infective (seventh-stage) nymphs, which retain the sixth stage cuticle as a protective sheath, are largely devoid of membranous secretion and these were dissected from cysts, washed, and surgically transplanted into the body cavities of naive and infected mice. Pronounced differences in the onset and intensity of the subsequent inflammatory response in the two categories of host indicate some form of specific recognition. In both groups of mice though, the cuticle is an eventual target for attack by effector cells, and parasites are killed. The protective function of SPC secretion is discussed.     

The ultrastructure of the alimentary tract of the skin-penetrating larva of Nippostrongylus brasiliensis (Nematoda)

The structure of the alimentary tract of the third stage infective larva of Nippostrongylus brasiliensis has been described. The cuticle which lines the buccal cavity and oesophagus differs from that which lines the mouth and covers the external surface of the nematode. The oesophagus is a cellular structure and is not, as previously thought, a syncytium. The secretory granules of the oesophageal glands are surrounded by multi-layered membranes which give a myelinated appearance to the granules. The cells of the oesophago-intestinal junction are lined with cuticle and are presumably part of the stomodaeum. The intestine is thin-walled and the cells bear short, widely spaced microvilli. The lumen of the intestine contains whorls of membranes which are probably phospholipid and could act as a food reserve for the larva. The rectum and anus are lined with cuticle.     

On the fine structure of the liquid producing floral gland of the orchid, Coryanthes speciosa

The flowers of the "bucket–orchid", Coryanthes speciosa , have two finger–like glands on each side of the column. They secrete large amounts of an aqueous fluid which drips into a bucket–like part of the labellum, the epichile. The fluid contains low amounts of sugars (glucose, fructose, saccharose, mannose), of ions, of a polysaccharide mucilage and unknown substances which provide odour and taste. The fluid seems to be discharged from the epithelial cells of the gland. They contain many dictyosomes, a well developed ER, occurring mainly as smooth, tubular interconnected elements, and coated pits at the plasmalemma as well as coated vesicles at the cell periphery and around the dictyosomes. Especially in young glands, the coated pits are frequently associated with lumps of osmiophilic material at the outer surface of the plasmalemma which are. however, observed also independent of coaled pits. The cuticle consists of an outer, homogeneous layer and an irregular, inner one. The latter is interspersed with a network of fibrils which merge into a mucilage that fills a voluminous subcuticular space in active plants. It is assumed that water secretion is the consequence of mucilage discharge and that the cuticle functions as a filter. The ER seems to supply the dictyosomes with membrane material. It is possible that the coated pits recycle membranes; an exocytotic function, however, cannot be excluded.     

Some ultrastructural observations on the integument of a pentastomid

The cuticle of the cephalobaenid pentastomid Reighardia sternae is described at various stages of the moult-intermoult cycle. The intermoult cuticle comprises four layers: an outer epicuticle; an underlying dense layer, the protein epicuticle; a fibrillar endocuticle; and a denser subcuticle. The overall similarity between the structure and composition of these layers and those of insects is discussed. However, the orientation of the chitin-protein fibres in the endocuticle does not show the rotating structure characteristic of many arthropod species, but this does appear in the sclerotized hooks. It is suggested that this comparatively loose, poorly oriented endocuticular structure produces a highly extensible cuticle which is precisely adapted to the specialized, endoparasitic habit of this species. Events at ecdysis, particularly the secretion of moulting fluid and the deposition of cuticulin, follow the insect pattern precisely. The phyletic significance of these observations is discussed.     

Light- and electron-microscopical studies on the structure of salt glands of Tamarix aphylla L.

Cuttings of Tamarix aphylla were grown in various concentrations of NaCl. Salt glands on newly developed branches were sectioned and examined, both with the light- and with the electron-microscope. An electron-dense material appears in cuttings grown in all concentrations of NaCl at the anticlinal walls of the innermost pair of secretory cells and, to some extent, on the surface of the gland above the cuticle. In the glands of cuttings grown in high concentration of NaCl this material also appears in large quantities, not only on top of the gland but also beneath the cuticle at the region of the median anticlinal wall of the outermost pair of secretory cells. The material beneath the cuticle is connected to the electron-dense material on the outer surface of the cuticle via the secretory pores. It is suggested that this material is of pectic nature and forms a continuous system with the walls and wall protuberances of the secretory cells which are also very rich in pectic substances. As pectic substances absorb solutions easily they may enhance the transport of salt.
Many proplastids, vacuoles with simple structure and others with infolded membranes as well as numerous mitochondria were observed in the secretory cells. In the walls between the collecting cells and the innermost secretory cells there are numerous plasmodesmata with characteristically arranged membranes.     

Polarized secretion of an ectopic protein in Drosophila salivary glands in vivo.

Epithelial cells can secrete specific proteins in a polarized manner, either from the apical or basolateral surface. Intracellular protein sorting which results in polarized secretion has previously been studied using epithelial tissue culture cells. We describe here the use of Drosophila larval salivary glands for the study of polarized secretion by epithelia in vivo, and address whether an ectopically synthesized secretory protein can be sorted and targeted to the correct cell surface for secretion. Larval cuticle proteins (LCPs) and salivary gland secretion (Sgs) proteins of Drosophila melanogaster are apically secreted proteins that are produced respectively by the epidermis and salivary glands. We have transformed Drosophila with a hybrid gene consisting of the sgs-4 promoter sequence and the coding sequence for a variant (LCP-f2) of LCP-2. We have found that transgenic late third instar larvae produce LCP-f2 only in the salivary glands and that LCP-f2 is properly secreted in vivo in a polarized manner from only the apical surface of the cells into the gland lumen. The results indicate that apical secretion does not depend on a tissue-specific targeting signal contained within the protein.     

CUTICLE DEVELOPMENT ON GLANDULAR TRICHOMES OF CANNABIS SATIVA (CANNABACEAE)

The dermal sheath of glandular trichomes of Cannabis sativa L., consisting of cuticle and a subcuticular wall, was examined by transmission electron microscopy. Cuticle thickened selectively on the outer wall of disc cells of each trichome prior to formation of the secretory cavity, whereas thickening was less evident on the dermal cells of the bract. Membraned secretory vesicles that differ in size and appearance in the secretory cavity were the source of precursors for synthesis of cuticle. Vesicle contents, released following the degradation of the vesicle membrane upon contact with the subcuticular wall, contributed to both structured and amorphous phases of cuticle development. The structured phase was represented by deposition and thickening of cuticle at the subcuticular wall-cuticle interface to form a thickened cuticle. In the amorphous phase precursors permeated the cuticle in a liquid state, as shown by fusion of cuticles and wax layers between contiguous glands, and may have contributed to growth in surface area of the expanding sheath. Disc cells are interpreted to control growth of secretory cavity by secretion of membraned vesicles into the cavity. The thickened cuticle, which increased eightfold in thickness during enlargement of the gland, provided structural strength for the extensive surface area of the dermal sheath. The gland of Cannabis in which vesicle contents contribute to the growth in thickness and surface area of the cuticle of the sheath is interpreted to represent a phylogenetically derived state as contrasted to secretory glands possessing only cuticle and lacking a complement of secretory vesicles.     

Structure of the integument in Paranthessius anemoniae claus,a copepod associate of the snakelocks anemone Anemonia sulcata (Pennant)

The integument of Paranthessius anemoniae has been studied with light and electron microscopy. A cuticle with clearly defined epicuticular, exocuticular and endocuticular regions overlies a cellular hypodermal layer. The distribution of carbohydrate, lipid and protein components of the cuticle were demonstrated histochemically. Parabolic striations in oblique sections of cuticle suggest that its molecular architecture fits a “twisted sheet” theory proposed for other species. Arthrodial membranes at body and limb joints have a homogeneous structure, lacking exocuticle and endocuticle. Subcuticular glands appear to secrete substances thought to be responsible for the immunity which Paranthessius seems to have to the nematocysts of its host. Small hairs, situated in cuticular cups which occur over the dorsal body surface are considered to function as rheoreceptors.     

Ultrastructure of the wax-gland system in subterranean scale insects (homoptera,coccoidea, margarodidae)

The ultrastructure of wax glands (integumentary, stigmatic, and peristigmatic glands) was investigated in larvae, cysts, and adult females and males of species belonging to the genera Porphyrophora, Sphaeraspis, and Eurhizococcus. The general organization and cytological characteristics are similar for all glands studied. Each gland is composed of a single layer of 8 to 40 cells. The glandular cells are characterized by a very large quantity of smooth endoplasmic reticulum which forms dense zones throughout the cytoplasm, but is always placed near the collecting canals in the presence of mitochondria. Each cell has a central canal reservoir which penetrates it deeply and gives rise to a large number of lateral collecting canals, formed by the invagination of the apical plasma membrane. The canals open into a subcuticular cavity forming a common reservoir in which the secretion is accumulated. This reservoir is covered by a modified cuticle formed from the endocuticle and the epicuticle. The endocuticle is composed of a network of fine tubular structures and has many filaments on its surface. The epicuticle is perforated by numerous pores. There is no cuticular duct. The secretion crosses the cuticle in three successive steps. First, it passes through the filaments, then through fine tubular structures of the endocuticle, and finally through the epicuticular pores.     

Accessory Pollen Adhesive from Glandular Trichomes on the Anthers of Leonurus sibiricus L. (Lamiaceae)

Abstract: Glandular trichomes (ca. 16 per anther) on the anthers of Leonurus sibiricus produce a secretion that, when touched, is liberated at once and becomes sticky when in contact with the air. With successive visitations of the pollinators (species of Bombus in naturalized populations) the number of secretion‐containing glands on each anther diminishes by mechanical rupture. On the pollinators, the secretion mixed with pollen was found adhered to the integument on the parts making contact with the anthers and stigma, mostly on the scape of the antennae. These trichomes are anatomically identical to the glandular scales common in the entire family and are formed by a multicellular cuticle‐bounded structure, with a foot and head. The secretion is accumulated as a milky emulsion under the cuticle, outside the primary cell wall, and is liberated by rupture of the cuticle. The composition possibly differs from what generally distinguishes these glandular trichomes, i.e. volatile oils that give these plants their particular smell. Such volatile compounds are generally assumed to have defensive or attractive functions, different from those observed in this study, which would be strictly mechanical.     

Ultrastructural investigation of a salivary gland in a centipede: structure and origin of the maxilla I-gland of Scutigera coleoptrata (Chilopoda, Notostigmophora)

The maxilla I-gland of Scutigera coleoptrata was investigated using light and electron microscopy methods. This is the first ultrastructural investigation of a salivary gland in Chilopoda. The paired gland opens via the hypopharynx into the foregut and extends up to the third trunk segment. The gland is of irregular shape and consists of numerous acini consisting of several gland units. The secretion is released into an arborescent duct system. Each acinus consists of multiple of glandular units. The units are composed of three cell types: secretory cells, a single intermediary cell, and canal cells. The pear-shaped secretory cell is invaginated distally, forming an extracellular reservoir lined with microvilli, into which the secretion is released. The intermediary cell forms a conducting canal and connects the secretory cell with the canal cell. Proximally, the intermediary cell bears microvilli, whereas the distal part is covered with a distinct cuticle. The cuticle is a continuation of the cuticle of the canal cells. This investigation shows that the structure of the glandular units of the salivary maxilla I-gland is comparable to that of the glandular units of epidermal glands. Thus, it is likely that in Chilopoda salivary glands and epidermal glands share the same ground pattern. It is likely that in compound acinar glands a multiplication of secretory and duct cells has taken place, whereas the number of intermediary cells remains constant. The increase in the number of salivary acini leads to a shifting of the secretory elements away from the epidermis, deep into the head. Comparative investigations of the different head glands provide important characters for the reconstruction of myriapod phylogeny and the relationships of Myriapoda and Hexapoda.     

Fine structure of the spermatheca and of the accessory glands in Orchesella villosa (Collembola, Hexapoda)

The spermatheca and the accessory glands of the collembolan Orchesella villosa are described for the first time. Both organs exhibit ultrastructural differences, according to the time of the intermolt in which the specimens were observed. A thick cuticular layer lines the epithelial cells of the accessory glands. In the reproductive phase, they are involved in secretory activity; a moderately dense secretion found in the apical cell region opens into the gland lumen. Cells with an extracellular cistern are intermingled with the secretory cells. These cells could be involved in fluid secretion, with the secretory product opening into the cistern which is filled with an electron-transparent material. After the reproductive phase, the gland lumen becomes filled with a dense secretion. The accessory gland secretion may play a protective role towards the eggs. The spermatheca is located between the accessory glands; its epithelium is lined by a thin cuticle forming spine-like projections into the lumen and consists of cells provided with an extracellular cistern. Secretory cells, similar to those seen in the accessory glands, are missing. Cells with a cistern could be involved in the production of a fluid secretion determining sperm unrolling and sperm motility.     

Ultrastructure of the male reproductive accessory glands in the medfly Ceratitis capitata (Diptera: Tephritidae) and preliminary characterization of their secretions

The morphology and the ultrastructure of the male accessory glands and ejaculatory duct of Ceratitis capitata were investigated. There are two types of glands in the reproductive apparatus. The first is a pair of long, mesoderm-derived tubules with binucleate, microvillate secretory cells, which contain smooth endoplasmic reticulum and, in the sexually mature males, enlarged polymorphic mitochondria. The narrow lumen of the gland is filled with dense or sometimes granulated secretion, containing lipids. The second type consists of short ectoderm-derived glands, finger-like or claviform shaped. Despite the different shape of these glands, after a cycle of maturation, their epithelial cells share a large subcuticular cavity filled with electron-transparent secretion. The ejaculatory duct, lined by cuticle, has epithelial cells with a limited involvement in secretory activity. Electrophoretic analysis of accessory gland secretion reveals different protein profiles for long tubular and short glands with bands of 16 and 10 kDa in both types of glands. We demonstrate that a large amount of accessory gland secretion is depleted from the glands after 30 min of copulation.     

The cytochemical localization of adenylate cyclase activity in mucous and serous cells of the salivary gland

The present study was undertaken to localize adenylate cyclase activity in salivary glands by cytochemical means. For the study, serous parotid glands and mixed sublingual glands of the rat were used. Pieces of the fixed glands were incubated with adenosine triphosphate (ATP) or adenylyl-imidodi-phosphate (AMP-PNP) as substrate: inorganic pyrophosphate or PNP liberated upon the action of adenylate cyclase on the substrates is precipitated by lead ions at their sites of production. In both glands, the reaction product was detected along the myoepithelial cell membranes in contact with secretory cells, indicating that a high level of adenylate cyclase activity occurs in association with these cell membranes. The association with a high level of the enzyme activity might be related to the contractile nature of myoepithelial cells which are supposed to aid secretory cells in discharging secretion products. A high level of adenylate cyclase activity was also detected associated with serous secretory cells (acinar cells of the parotid gland and demilune cells of the sublingual gland), but not with mucous secretory cells. In serous cells, deposits of reaction product were localized along the extracellular space of the apical cell membrane bordering the lumen. This is the portion of the cell membrane which fuses with the granule membranes during secretion. Since the granule membranes are not associated with a detectable level of adenylate cyclase activity, it appears that the enzyme activity becomes activated or associated with the granule membranes as they become part of the cell membrane by fusion. The association with a high level of adenylate cyclase activity appears to be related to the ability of the membrane to fuse with other membranes. It is likely, since the luminal membrane of mucous cells which does not fuse with mucous granule membranes during secretion is not associated with a detectable enzyme activity.     

THE ULTRASTRUCTURE OF THE SALT GLANDS OF CYNODON AND DISTICHLIS (POACEAE)

The epidermal salt glands of the grasses Cynodon and Distichlis consist of a small outer cap cell and a large, flask-shaped basal cell. The wall of the basal cell is contiguous with those of the adjacent epidermal cells and underlying mesophyll cells. The basal cell is connected symplastically with all adjoining cells via plasmodesmata. The outer, protruding portion of the glands is covered by a cuticle continuous with that of the adjoining epidermal cells. However, the lateral cell walls of the glands are not incrusted by this cuticle. The cap cell wall has a loose, mottled appearance quite different from the compact striated appearance of the basal cell wall. The cap cell is characterized by dense cytoplasm containing many organelles and a varying number of small vacuoles. The basal cell cytoplasm is distinguished by the presence of an intricate system of paired membranes that are closely associated with mitochondria and microtubules. These membranes are infoldings of the plasmalemma that originate adjacent to the wall separating the cap and basal cells. The space enclosed by the paired membranes, therefore, is an extracellular channel that is open only in the direction of secretory flow. The consistent orientation of this system of paired membranes suggests that it represents a structural specialization which is directly and functionally involved in the secretory process. The close association of mitochondria and microtubules with the paired membranes implies that these structures are also functionally related to the secretory process. Finally, the results of this study indicate that these glands are ultrastructurally similar to those of Spartina and that the glands of these three grasses are structurally distinct from those of dicotyledonous plants.     

Fine structure and histochemistry of the epidermis of the fish Monopterus cuchia

An attempt is made to correlate fine structure with the histochemical reactions of the epidermis in the synbranchiform fish Monopterus cuchia. Three sources of mucus are identified. Superficial epithelial cells produce weakly acidic glycoprotein which is secreted at the surface as the external mucous layer or cuticle. Numerous large unicellular mucous glands have a secretion which is strongly acidic and sulphated, although the basal and peripheral parts of these cells, which contain most of the rough endoplasmic reticulum, react strongly for neutral glycoprotein; Golgi cisternae appear to be involved in a change of histochemical reaction from neutral to strongly acidic as the secretion is formed. A second, slender, type of mucous gland cell, not previously reported, gives a weaker reaction for sulphated acidic glycoprotein and has cytoplasm with numerous Golgi cisternae and free ribosomes, producing electron–dense secreted drops. Sacciform cells, with a protein–aceous secretion, have a characteristic fine structure with membranous "bubbles" at the surface of the cytoplasm. Ionocytes, sensor) cells and intrusive leucocytes have been identified in the epidermis.     

Control of prothoracic gland activity in larvae of Galleria mellonella

Prothoracic glands of last instar wax moth larvae maintain spontaneous secretory activity both in decapitated larvae and in isolated abdomens into which they have been transplanted, as judged by their ability to induce secretion of a new cuticle. Their activity is hormonally stimulated by the brain and inhibited by the prothoracic and mesothoracic ganglia. The subesophageal ganglion seems to suppress the inhibitory influence of the thoracic ganglia. The prothoracic glands of larvae decapitated at different times during the last instar all respond to brain implantation, and this response does not change when brains are implanted at increasing intervals after decapitation. The prothoracotropic activity of the isolated brain is highest in brains of pupae and adults but is relatively and consistently low in brains of last instar larvae. The results demonstrate that the control of prothoracic glands is a complex process governed by the nervous integration of various stimuli.     

Apolysis and the turnover of plasma membrane plaques during cuticle formation in an insect.

The apical plasma membranes of Calpodes epidermal cells have small fattened areas or plaques with an extra density upon their cytoplasmic face. The plaques are typically at the tips of microvilli. The are present during the deposition of fibrous cuticle and the cuticulin layer. Since the plaques are close (less than 15nm) to the sites where these kinds of cuticle first appear, they are presumed to have a role in their synthesis and/or deposition and orientation. When fifth stage larval cuticle deposition ceases prior to pupation, the plaques are lost as the area of the apical plasma membrane is reduced. The plaques pass from the surface into pinocytosis vesicles and multivesicular bodies where they are presumably digested. The loss of plaques occurs as the blood level of moulting hormone reaches a peak at the critical period after which the prothoracic glands are no longer needed for pupation. Apolysis or separation of the epidermis from the old cuticle is the stage when plaques are absent, the old ones have been lost but the new ones have yet to form. After the critical period, the epidermis prepared for pupation with a phase of elevated RNA synthesis at the end of which plaques and microvilli reform in time to secrete the new cuticulin layer and later the fibrous cuticle of the pharate pupa. There is a new generation of plaques for each moult and succeeding intermoult and each generation is involved in two kinds of cuticle deposition before involution and redifferentiation.