Studies on the posterior silk gland of the silkworm Bombyx mori. V. Electron microscope localization of fibroin in the posterior silk gland at the later stage of the fifth instar

Electron microscope observations of thin sections of epoxy resin- embeded posterior silk gland cells at the later stage of the fifth instar revealed that the Golgi vacuoles and the secretory granules (fibroin globules) in the cytoplasm and the glandular lumen contain fine fibrous materials. In frozen thin sections these structures appear as electron-dense granules and electron-dense blocks, or a column, respectively. Immunoelectron microscopy has shown that ferritin particles or products of the peroxidase reaction are localized on these structures. It was concluded that the fine fibrous materials most probably represent native fibroin molecules or their aggregates.     

Ultrastructure of posterior silk gland cells and liquid silk in Indian tasar silkworm,Antheraea mylitta drury (Lepidoptera : Saturniidae)

The ultrastructural characteristics of the posterior silk glands of the mature Antheraea mylitta (Lepidoptera : Saturniidae) larvae were clarified. Fibroin globules containing a small dense mass of fibroin fibers are produced in Golgi vacuoles, and released from the apical surface into the lumen by exocytosis. Bundles of microfilaments, which serve as a dynamic skeleton, are well developed. Numerous autophagosomes originating; from mitochondria accumulate in both basal and apical ends of the gland cell; the degenerated materials are released in the basement membrane and into the gland lumen, respectively. These materials invade the central fibroin column, leaving digested vacuoles in the fibroin cocoon filament. Ours may be the first finding of this rare phenomenon in which the degenerated lysosomes originated from mitochondria in both liquid silk in the lumen and cocoon filament.     

Transformation of the endostyle of the anadromous sea lamprey,Petromyzon marinus L., during metamorphosis. II. Electron microscopy

Electron microscopy was used to follow the transformation of the endostyle to a thyroid gland in the anadromous sea lamprey, Petromyzon marinus L., throughout metamorphosis (stages 1–7). Transformation of the larval (ammocoete) endostyle begins at the first signs of external change (stages 1–2), and the adult form of the gland is reached by stage 5. Only slight modifications of the gland accompany further development to the end of metamorphosis. Development of the thyroid gland involves degeneration, proliferation, and reorganization of the cells in the endostyle, and changes in their fine structure. Ultrastructural changes during early stages are most obvious in the type 1 cells that make up the shrinking glandular tracts, and involves the accumulation of cytoplasmic microfilaments and a variety of cytoplasmic inclusions. The glandular tracts and their cells gradually disappear through autolysis and, apparently, through phagocytosis by neighboring epithelial cells and macrophages. Although the fine structure of the type 2, 3, 4, and 5 cells is not altered in the early stages, by stage 3, many of these cells become either vacuolated, undergo autolysis, or are extruded. Phagocytosis of some of each of these cell types likely occurs. Thyroid follicles are first observed during stage 4. Some of their lumina seem to arise from the accumulation of material in intercellular spaces and from vacuoles among cell clusters. Other lumina may represent a portion of the original lumen of the endostyle. Many follicles appear to be comprised of cells with cytological characteristics similar to those of larval cell types 3 and 2c. Some of the other larval cell types, such as type 5, may also be involved. In young adult lampreys follicles are composed of cuboidal to columnar cells that lack the dilated cisternae of rough endoplasmic reticulum seen in follicular cells of higher vertebrates. Dense collagenous connective tissue surrounding the follicles contains relatively few blood vessels. The transformation process described may have some relevance to our understanding of the development and evolution of the vertebrate thyroid gland.     

Developmental study of the ventral scent gland of the Mongolian gerbil]

Male and female in bred Mongolian gerbils aged 4, 5, 10, and 20 weeks were examined for the presence of a ventral scent gland macroscopically and histologically. It was found in about half of the gerbils aged 4 weeks and in all of the gerbils aged over 5 weeks. In adult male gerbils it weighed three times as much as in females. The ventral scent gland exhibited a sebaceous-like structure which consists of giant glandular cells with small vacuoles in the cytoplasm and the glandular cells displayed eosinophilic bodies contained within a duct, which are extruded through the lumen as holocrine-type secretion.     

Histochemical and ultrastructural evidence of lipid secretion by the silk gland of the sugarcane borer Diatraea saccharalis (Fabricius) (Lepidoptera: Crambidae)

The silk gland in Lepidoptera larvae is responsible for the silk production used for shelter or cocoon construction. The secretion of fibroin and sericin by the different silk gland regions are well established. There are few attempts to detect lipid components in the insect silk secretion, although the presence of such element may contribute to the resistance of the shelter to wet environment. This study characterizes the glandular region and detects the presence of lipid components in the secretion of the silk gland of Diatraea saccharalis(Fabricius). The silk gland was submitted to histochemical procedure for lipid detection or conventionally prepared for ultrastructural analyses. Lipid droplets were histochemically detected in both the apical cytoplasm of cell of the anterior region and in the lumen among the microvilli. Ultrastructural analyses of the anterior region showed lipid material, visualized as myelin-like structures within the vesicular Golgi complex and in the apical secretory globules, mixed up with the sericin; similar material was observed into the lumen, adjacent to the microvilli. Lipids were not detected in the cells neither in the lumen of the posterior region. Our results suggest that the silk produced by D. saccharalis has a minor lipid content that is secreted by the anterior region together with the sericin.     

Ultrastructure of the excretory duct in the silk gland of the sugarcane borer Diatraea saccharalis (Lepidoptera: Pyralidae)

The excretory duct in the silk gland of the sugarcane borer Diatraea saccharalis consists of two morphologically distinct regions, recognized by scanning and transmission electron microscopy. The thin posterior region, adjacent to the glandular region, presents a regular surface. Secretory vesicles containing either electron-dense or fibrillar cuticular-like materials are observed in their apical cytoplasm; the same cuticular materials were detected as extracellular deposits among the microvilli. The short anterior region, near the common duct, exhibits surface protrusions; there are no secretory vesicles in their apical cytoplasm. These results show that only the duct cells at the posterior region are involved in the secretion of the cuticular intima elements. Desmosome-like structures were visualized linking together adjacent microvillar membranes only in the cells of anterior duct region, with unknown function. The transition between the duct and the glandular region is abrupt; the cells of the glandular and posterior duct regions present large amounts of microtubules. Nerve fibers can be observed between the duct cells in their two regions, suggesting that control of silk secretion may occur in the excretory duct via neurotransmitter liberation.     

Macromolecular array patterns of silk gland secretion in social Hymenoptera larvae

The cocoon, produced by most holometabolous insects, is built with silk that is usually produced by the larval salivary gland. Although this silk has been widely studied in the Lepidoptera, its composition and macromolecular arrangement remains unknown in the Hymenoptera. The macromolecular array patterns of the silk in the larval salivary gland of some meliponids, wasps, and ants were analyzed with polarized-light microscopy, and they were compared with those of Bombyx mori (Lepidoptera). There is a birefringent secretion in the glandular lumen of all larvae, due to filamentous structural proteins that display anisotropy. The silk in the distal, middle and proximal regions of the secretory portion of Formicidae and Vespidae glands presented a lattice optical pattern. We found a different pattern in the middle secretory portion of the Meliponini, with a zigzag rather than a lattice pattern. This indicates that the biopolymer fibers begin their macromolecular reorganization at this glandular region, different from the Formicidae and the Vespidae, in which the zigzag optical pattern was only found at the lateral duct. Probably, the mechanism of silk production in the Hymenoptera is a characteristic inherited from a common ancestor of Vespoidea and Sphecoidea; the alterations in the pattern observed in the Meliponini could be a derived characteristic in the Hymenoptera. We found no similarity in the macromolecular reorganization patterns of the silk between the Hymenoptera species and the silkworm.     

Degenerative changes and carotenoid uptake in the silk gland of the silkworm Bombyx mori

In the middle silk gland of the silkworm Bombyx mori, especially in the middle region, structural changes were studied in relation to absorbing activity, using a transplantation method. The physiologically active gland, which was prepared by the decapitation at the feeding stage of the fourth larval instar, maintained a normal structure when placed in the larval body cavity during the middle stage of the fourth instar or during the early stage of the fifth (last) larval instar. But, if the gland was placed there during the fourth larval-larval pharate stage, histolytic changes, e.g. invagination of tunica propria, its separation from the cell and contraction of the cell, took place in the tissue. These results suggest that, once activated, cells in the middle region of the middle silk gland undergo degenerative changes even in the presence of the corpus allatum hormone during the larval-larval pharate period.     

Silk Production after Mechanical Pulling Stimulation in the Ampullate Silk Glands of the Barn Spider, Araneus cavaticus

Synthesis of protein by the major ampullate silk glands in the barn spider, Araneus cavaticus was stimulated by depleting the storage of silk protein in the ampulla by mechanically pulling fiber from the spigot. After this treatment, fine structural changes of the glandular epithelium during silk production were examined using light and transmission electron microscopes. In the process of rapid production, major secretory silk was synthesized at the tail region via rER of glandular epithelial cells, and was transported into the ampulla region. The mature secretory product in glandular epithelium appears almost spherical vacuoles which were grown up by fusion with the surrounding small vesicles including the secretory silk. Unlike to a typical process of the secretion, the ampullate silk of tail region seems to bypass either concentrating or packaging steps by the Golgi apparatus. However there's no doubt that the Golgi apparatus also play an important role in the secretory process of the ampulla region. After mechanical pulling stimulation, both epithelia of ampulla and tail regions appeared as a thinner layer of columnar cells with less definitive cell membrane. There are few secretory droplets within these cells, thus causing this region to stain much lighter. It is obvious that the cell loses part of its cytoplasm in this process, and disorganization of the secretory product occurs when it is extruded from the cells by a apocrine release.     

The post-embryonic changes in Melipona quadrifasciata anthidioides Lep. (Hym. Apoidea). II. Development of the salivary glands system

The paper deals with the development of the salivary gland system in Melipona quadrifasciata anthidioides, which begins in the prepupal stage. The silk glands degenerate by autolysis at the end of the larval stage. Degeneration is characterized by cytoplasmic vacuolization and pycnosis of the nuclei of the secretory cells. The glandular secretory portion of degenerated silk glands separates from the excretory ducts. The salivary glands develop from the duct of the larval silk glands. The thoracic salivary glands develop from the ducts of the secretory tubules and the head salivary glands from the terminal excretory duct. The mandibular glands appear in the prepupa as invaginations of mandibular segments, and their differentiation to attain the adult configuration occurs during pupation. The hypopharyngeal glands have their origin from evaginations of the ventral anterior portion of the pharynx. A long tubule first appears with walls formed by more than one cellular layer. Then some cells separate from the lumen of the duct, staying attached to it by a cuticular channel in part intracellular. The initial duct constitutes the axial duct, in which the channel of the secretory cells opens. During the development of salivary and mandibular glands, they recapitulate primitive stages of the phylogeny of the bees. During the development of salivary glands system, mitosis accounts for only part of the growth. Most of the growth occurs by increase in size of cells rather than by cell division. In brown-eyed and pigmented pupae six days before emergence, the salivary gland system is completely developed, although not yet functioning.     

Ultrastructural changes in the oviduct of the laying hen during the laying cycle

The ultrastructural changes occurring in the fully functional oviduct of Isa Brown laying hens were studied during various stages of the laying cycle. Hens were killed at different positions of the egg in the oviduct. The oviduct was lined by ciliated and non-ciliated cells (also referred to as granular cells). The granular cells in the infundibulum contributed to secretion during egg formation, whereas ciliated cells showed little evidence of secretion. Ultrastructural changes were recorded in the granular and glandular cells of the distal infundibulum. In the magnum, the surface ultrastructure revealed glandular openings associated with the ciliated and granular cells. Cyclic changes were recorded in the glandular cells of the magnum. With respect to the three observed types of glands, the structure of gland type A and C cells varied at different egg positions in the oviduct, whereas type B cells represented a different type of gland cell containing amorphous secretory granules. The surface epithelium of the isthmus was also lined by mitochondrial cells. Two types of glandular cell (types 1 and 2) were recorded in the isthmus during the laying cycle. Intracisternal granules were found in type 2 cells of the isthmus. A predominance of glycogen particles occurred in the tubular shell gland. The granular cells in the shell gland contain many vacuoles. During egg formation, these vacuoles regressed following the formation of extensive rough endoplasmic reticulum; the reverse also occurred. The disintegrated material found in the vacuoles may have been derived from the disintegrating granules. The Physiology Teaching Unit, University of New England, provided financial support to K. Chousalkar for this study.     

Ultrastructure of Lyonet's gland in the silkworm (Bombyx mori L.)

The gland cells of Lyonet's gland, which is accessory to the silk gland in the silkworm larva, is characterized by the presence of complicated canaliculi bearing microvilli on their inner surface, large numbers of mitochondria and remarkably convoluted basal plasma membrane. On the other hand, the cell lacks the well-developed cytoplasmic membrane system such as rough- and smooth-surfaced endoplasmic reticula and Golgi bodies, though free ribosomes are numerous. Secretory vesicles are absent, and the canaliculi contain no dense material. From such ultrastructural observations, it was suggested that a possible role of the gland may be the exchange of the small molecules such as water and ions, rather than the hitherto supposed secretory role of a cementing sunstance of silk proteins. The lumen of the proximal part of the glandular duct contains a kind of proteinaceous substance which can be demonstrated histochemically and is regarded as similar to one of the silk proteins in the silk gland, not to the real product of the Lyonet's gland.     

Cell differentiation during the ontogeny of larval salivary glands of the fly, Telmatoscopus albipunctatus

Using the larvae, pharate pupa, and pharate adults of the moth fly, Telmatoscopus albipunctatus, histological and ultrastructural features of the salivary glands were investigated. The gland lumen contains a milky secretion from the first instar. This secretion continues to ccur at all subsequent developmental stages; with the onset of the pharate pupal stage, however, the secretion becomes transparent and rather viscous. Histochemical tests revealed that it is mainly proteinaceous. Glands from the same developmental stage may respond differently to PAS-reaction.Various cell organelles were compared at consecutive stages of larval development and of secretory activity of the salivary glands. In first and second instar larvae autophagic vacuoles are virtually absent in the salivary gland cells. They were occasionally found in the third instar, when they appear to be engaged in the process of organelle turnover. Histolysis of the larval glands is initiated towards the close of the fourth instar when the number of autophagic vacuoles starts to increase. Simultaneously, the cytoplasm, previously full of ribosomes and endoplasmic reticulum, starts losing these structures. At the beginning of the pharate adult stage, the cytoplasm becomes practically devoid of all structures other than those engaged in autophagy.Polyteny of the chromosomes during ontogeny of the larval salivary glands is also discussed.     

Structure and function of the glandular vas deferens in Ascaris suum (Nematoda).

The glandular vas deferens in the linearly arranged male reproductive tract in Ascaris suum produces substances which cause marked morphological and physiological changes in the spermatozoa. The glandular secretions, presumably formed by the rough endoplasmic reticulum and Golgi saccules, are extruded from the cells and coalesce to form homogeneous masses in the gland lumen. In sexually inactive worms the secretory material is separated from the spermatozoa by a sphincter comprised of neuro-muscular-like cells. During copulation the sphincter lumen enlarges and the spermatozoa and sperm-activating glandular material are mixed and simultaneously transferred to the female worm.     

Enzyme Histochemistry as a Link between Biochemistry and Morphology

A study has been made of the progress of involution of the mouse and rat mammary gland using histologic, electron microscopic, histochemical and autoradiographic methods. Particular emphasis has been placed on the morphology, metabolic alte-rations and activities of histochemically identifiable enzymes, and on the pharmacologic effects of lactation inhibiting agents and cytostatic drugs on lactation and involution. In order to allow a systematic investi-gation, involution was initiated in rats and mice by ligation of individual gland ducts at various time intervals. Both lactating glands and glands in different phases of involution were thus available in a given animal.The most important observation was that involution, which altogether takes approximately 2 weeks to be complete, involves a three-phase process, each phase being clearly distinguishable by morphologic and histochemical criteria. The first phase comprises approximately 4 days during which production of milk may be reinitiated. The second phase starts on day 5 of involution and constitutes the period of involution per se characterized by appreciable parenchymal cell degradation. The third phase, which starts around day 10, is the period of reorganization to the resting mammary gland.Early in the first phase of involution, substantial alveolar enlargement due to engorgement with milk, together with epithelial flattening, are prominent features. By day 3, the glandular contents decrease again in volume, the number of glandular cells and the constituent cytoplasmic organelles remaining unchanged during this period, except for the diminished appearance of fat droplets. In addition to normal appearing vacuoles with only occasional or sparse protein granules, giant vacuoles containing, in part, several hundred casein granules are found. Their formation appears to be due to increased stacking of granules in distended vacuoles prior to dissociation from the Golgi apparatus. In addition, however, the enhanced reactions of a1P (alkaline phosphatase) and ATPase, which are found in the apical plasmalemma, are suggestive of resorptive activities. Protein particles absorbed from the glandular lumen equally appear to have a capacity for fusing into large vacuoles. The large protein granule-containing vacuoles regularly exhibit intense (3-Glu activity. This enzyme would appear to contribute actively to the degradation of excess milk during the first phase of involution.Autoradiographic studies reveal that the synthesis and release of proteins into the secretion is maintained for 3 days. While 3H-tyrosine uptake by the alveolar cells continues unchanged, the incorporation of 3H-palmitic acid into glandular lipoids, and of 3H-fucose into glandular polysaccharides is virtually blocked completely. An immediate reaction of the lipoid metabolism is also indicated by the decrease in 3HBDH activity on the first day of involution.The activities of the histochemically detected oxidoreductases (LDH, MDH, SDH, G6PDH, 3HBDH) show a sharp fall on day 1 of involution, reaching levels approximately one half of the activity observed during lactation, as shown on micro densitometry. The activities remain unchanged during the following 4 days.No degradation of glandular parenchyma is noted during the-first phase of involution. The glandular cells rather take a -wait-and-see- attitude which enables them to participate again in the secretion of milk, as need arises. At this time the activities of the enzymes implicated in energy metabolism have reached approximately the resting mammary gland level. Only protein synthesis is maintained virtually unrestricted and this results in the production of excess milk constituents that are degraded as soon as they are being formed.In the second phase of involution, large seg-ments of the glandular epithelium undergo invo-lution, a process which involves the destruction of glandular epithelial cells and the removal of the resulting cellular debris from the mammary gland. The glandular cells remaining are transformed into resting cells. The lysosomes of the glandular epithelial cells, with maximum numbers being attained between days 7 to 9, contribute decisively to this degradative process. Ultra-structurally, this stage is initially characterized by the appearance in the alveolar cell cytoplasm of segregated cytoplasmic areas which stain negatively for acP (acid phosphatase) and are rich in organelles. These cytoplasmic areas change to membrane-bordered lysosomes which possess intense acP activity. The lysosomes are obviously required for the autophagic degradation of cytoplasmic segments. At the same time the activities of other lysosomal enzymes, involving acP, N-A-Gase, AMPase and AS, show a sharp increase. ATPase and TPPase likewise exhibit considerably increased activity during the second phase of involution. It is seen on microdensitometry that during this phase the acP attains approximately three times the lactation activity. In contrast, the activity of (3-Glu, after having shown a very high increase during the first phase, reverts again to the resting mammary gland level.During the second phase of involution, the oxidoreductases are subject to a further drastic decline of their activities. This process, which consistently affects all segments of the mammary gland,,comes to completion within a few hours. The reaction is found to be minimal around day 5 of involution, at a time when the enzyme activities are approximately one quarter of the lactation levels.At this time, many alveolar cells are destroyed and released into the glandular lumen, the acP retaining its activity in the lysosomes of sloughed cells or cell debris. The resulting gaps in the alveolar epithelium are either bridged immediately or remain detectable on histology. Yet the glandular contents do not pass into the interstitial tissue. The adherence of the glandular tree and the glandular epithelium is ensured by myoepithelial cells. The basement membrane effects the complete segregation of the parenchyma from the interstitial tissue:Macrophages which at this stage occur increa-singly near the alveoli, in the alveolar epithelium and in regional lymph nodes, and which are conspicuous due to numerous acP-laden lysosomes participate essentially in glandular regression.The third phase of involution, which takes place approximately 10 to 14 days following the onset of milk stasis, is the period of reorganization to the resting mammary gland, a period during which glandular cells containing little cytoplasm and sparse organelle lining make their appearance. However, the activities of acP and other lysosomal enzymes remain elevated compared to the pregestational level. Histochemically, the reaction of the oxidoreductases is more intense than during the second involutionary phase, corresponding roughly to the level of the mammary gland in the resting state. The formation of the glandular epithelial cells of the resting mammary gland is not due to renewed mitotic activity, but results from the reduction of actively secreting epithelial cells.Throughout the period of involution the myo-epithelium consistently changes its shape. How-ever, cytoplasmic alterations are not discernible on electron microscopy, nor do these cells undergo degradation during glandular involution. The alP reaction is of particular value for the identification of the myoepithelial cells. No alteration in enzyme activities is demonstrable at the histochemical level throughout the process of involution.Alterations in the interstitial tissue affect particularly the adipose tissue. During lactation, the interalveolar space exhibits only a narrow connective tissue layer which changes insignificantly during the first phase of involution, whereas the subsequent incorporation of lipids results in the formation of plurilocular lipid cells and the reappearance of unilocular adipose tissue as involution advances. During this period the vessels move away from the alveoli.The response of the mammary gland to lactation inhibiting and cytostatic drugs varies, depending on the agent administered. Estrogencontaining drugs lead to an involutionary process which in its initial phase differs from that observed during normal glandular regression. Due to the fact that the milk continues to be suckled by the young, milk production however ceasing very rapidly, the (3-Glu activity is not found to increase greatly during the first phase of involution. The behavior of the lysosomal enzymes during the second phase resembles that seen during normal involution.After administration of the ergot alkaloid 2-Br-a-ergokryptine methane sulfonate (CB 154), the process of involution is initiated only in individual mammary gland cells if the young are left with the mother. In these areas involution takes a normal course. Altogether, milk production changes only insignificantly.The cytostatic drug 5-fluorouracil does not induce direct involution. Milk production apparently is not arrested. However, the pups, when left with the mother, die after 5 to 6 days. Death would appear to be due to the cytotoxic action of 5-fluorouracil.     

Lipid distribution in salivary glands of larvae and adult bees (Hymenoptera: Apidae)

Cytochemical studies were carried out to establish lipid distribution in the salivary glands of larvae and adult bees, using the imidazole buffer technique. In the duct cells of the larval salivary gland, the reaction was positive in the epicuticle and negative in the glandular lumen. The absence of smooth endoplasmic reticulum and the presence of lipids in the intercellular space suggest that lipids absorbed from the haemolymph could be used in the constitution of the epicuticle, after having been conveyed through the epithelium. In adult workers (new-emerged, nurse and forager workers), the head salivary glands presented a positive reaction in the secretion in glandular lumen, identifying its lipidic nature.     

Electron microscopic observations of Orientia tsutsugamushi in salivary gland cells of naturally Infected Leptotrombidium pallidum larvae during feeding

We performed a detailed electron microscopic observation on the escaping process of Orientia tsutsugamushi from the salivary gland cells of naturally infected trombiculid larvae into the acinar lumen of the gland during feeding on mice. In unfed larvae, many O. tsutsugamushi were intermingled with secretory granules in the cytoplasm of the salivary gland cell. O. tsutsugamushi was neither found in the acinar lumen nor observed escaping from the apical surface of the gland cell. In contrast, in the larvae fed on mice, many O. tsutsugamushi were observable in the acinar lumen. They were enveloped with the host glandular cell membrane. In salivary gland cells, secretory granules changed the distribution and accumulated in the apical region. In such cells, the majority of O. tsutsugamushi were found at the base of the cell. Some O. tsutsugamushi were pushing the glandular cell membrane outward in various degrees, showing different stages of escape. These findings suggest that larval feeding induced O. tsutsugamushi escape from salivary gland cells, that the escape was by budding, during which O. tsutsugamushi were enveloped in the host cell membrane, and that O. tsutsugamushi would be injected into the mouse skin as a mixture with mite saliva. The study also revealed the presence of many small vesicles that had the same cell wall structure as O. tsutsugamushi in the cytoplasm of the salivary gland cell. Most of them seemed to be products from degenerated Orientia.