Anatomy and histology of the male reproductive system of the fire ant,Solenopsis invicta Buren (Hymenoptera : Formicidae)

The male reproductive system of the fire ant, Solenopsis invicta Buren (Hymenoptera : Formicidae), consists of the testes, vasa efferentia, vasa deferentia, seminal vesicles, accessory glands, ejaculatory duct, wedge, aedeagal bladder, and external genitalia. The testes in newly eclosed males appear as 4 large white lobes filled with packets of sperm. Each lobe of the testes contains only one follicle. As the testes degenerate, the maturing sperm migrate through the vasa efferentia and vasa deferentia into the seminal vesicles. The seminal vesicles attach to the accessory glands, which are lined with secretory columnar epithelium. The posterior ends of the accessory glands taper and unite to form the ejaculatory duct. A sclerotized wedge is found at the junction of the accessory glands and the ejaculatory duct. An aedeagal bladder, joining the ejaculatory duct posterior to the wedge, is lined with squamous epithelium enveloped by heavy musculature. The ejaculatory duct continues posteriorly to form a distal aedeagus surrounded by 3 pairs of valves, comprising the external genitalia.     

The adult musculature of two pseudostomid species reveals unique patterns for flatworms (Platyhelminthes,Prolecithophora)

We analyzed the adult musculature of two prolecithophoran species, Cylindrostoma monotrochum (von Graff, 1882) and Monoophorum striatum (von Graff, 1878) using a phalloidin-rhodamine technique. As in all rhabdithophoran flatworms, the body-wall musculature consisted of three muscle layers: on the outer side was a layer of circular muscle fibers and on the inner side was a layer of longitudinal muscle fibers; between them were two different types of diagonally orientated fibers, which is unusual for flatworms. The musculature of the pharynx consisted of a basket-shaped grid of thin longitudinal and circular fibers. Thick anchoring muscle fibers forming a petal-like shape connected the proximal parts of the pharynx with the body-wall musculature. Male genital organs consisted of paired seminal vesicles, a granular vesicle, and an invaginated penis. Peculiar ring-shaped muscles were only found in M. striatum, predominantly in the anterior body part. In the same species, seminal vesicles and penis only had circular musculature, while in C. monotrochum also longitudinal musculature was found in these organs. Female genital organs were only present in M. striatum, where we characterized a vagina interna, and a bursa seminalis. Transverse, crossover, and dorsoventral muscle fibers were lacking in the middle of the body and greatly varied in number and position in both species.     

Genesis of the reproductive system of mosquitoes II. Male of Aedes stimulans (walker)

The imaginal male of mosquitoes bears a combination of organs and appendages that make it morphologically distinctive. Its reproductive organs produce sperm cells, convey and extrude them, provide accessory fluids, and insure copulation and insemination. In Aedes stimulans (Walker) these organs are derived from one of the two sets of primordia provided by the embryo. The second set of primordia is capable of producing the feminine reproductive system under unusual circumstances. Testes are derived from two compact ovoid masses of cells suspended in the hemocoel of abdominal segment 6. Each enlarges slowly throughout larval instars 1–3 and elongates very rapidly late in instar 4. Specialization of the cellular mass into sperm cells proceeds forward from the caudal end early in pupal life. From the beginning, a sheath of nutritive cells or fatbody encases each gonad, and no tracheation of the mass is evident although one small trachea sends branches to the encasing fatbody late in larval life. The efferent canal from each testis is derived from a tenuous filament extending caudally from each gonad to the venter of segment 9 and a small cluster of cells in the wall of the hemocoel on the ental surface of imaginal disc 9. Early in pupal life the filaments become the tubular vasa efferentia. The caudal clusters are primordial terminal parts of the lateral tract that become vasa deferentia, seminal vesicles and associated accessory glands. The ejaculatory canal comes from a short pouch derived from the median genital plate of disc 9. All external parts except the paraprocts are products of disc 9. The bilateral buds begin to proliferate in larval instar 4 and become the basistyles, dististyles and claspettes of the gonapophyses during pupal life. The phallosome is derived from the median genital plate. Primordia of a possible feminine reproductive system and cerci remain undifferentiated and disappear early in pupal life in the normal course of events. Primordia that were recognizable include those of ovaries, parts of lateral oviducts, median genital tract and cerci.     

Morphology of gonoducts and male genital papilla, in the bluehead wrasse: implications and correlates on the control of gamete release

In the coral reef fish Thalassoma bifasciatum , males vary the number of sperm they release in successive spawnings with individual females in accordance with female body and clutch size. The morphology and histological structure of the male genital papilla, sperm duct, oviduct and surrounding musculature were examined in an effort to elucidate the mechanism permitting control of the number of gametes released during mating. In males, urinary and genital ducts pass separately through a common urogenital papilla and are associated with a striated sphincter muscle and a pair of thin, smooth ligament muscles arising from the first proximal anal fin radial and passing laterally around the sperm duct and oviduct. Within the papilla, the sperm duct resembles a narrow funnel whose inner walls contain longitudinal folds or septa protruding into the lumen of the duct. Dorsal to the papilla, the sperm duct enlarges and is divided into numerous, open chambers by irregular, longitudinal trabeculae. The wall of the duct and the trabeculae contain flat epithelium, smooth muscle and loose connective tissue. In females, the oviduct contains no trabeculae and is not divided into chambers. The ligament muscles are more thoroughly embedded in the sphincter muscle of the rectum than in males. Some ways in which these structures might control gamete release are suggested.     

Origin and development of the dorso-ventral flight muscles in Chironomus (Diptera; Nematocera)

The origin and development of the dorso-ventral flight muscles (DVM) was studied by light and electron microscopy in Chironomus (Diptera; Nematocera). Chironomus was chosen because unlike Drosophila, its flight muscles develop during the last larval instar, before the lytic process of metamorphosis. Ten fibrillar DVM were shown to develop from a larval muscle associated with myoblasts. This muscle is connected to the imaginal leg discso that its cavity communicates with the adepithelial cells present in the disc; but no migration of myoblasts seems to take place from the imaginal leg disc towards the larval muscle or vice versa. At the beginning of the last larval instar, the myoblasts were always present together with the nerves in the larval muscle. In addition, large larval muscle cells incorporated to the imaginal discs were observed to border on the area occupied by adepithelial cells, and are probably involved in the formation of 4 other fibrillar DVM with adepithelial cells. Three factors seem to determine the number of DVM fibres: the initial number of larval fibres in the Anlage, the fusions of myoblasts with these larval fibres and the number of motor axons in the Anlage. The extrapolation of these observations to Drosophila, a higher dipteran, is discussed.     

Morphology of male reproductive system in three species of Trypoxylon (Trypargilum) Richards (Hymenoptera: Crabronidae)

Variations in the adult male reproductive system among different groups of Hymenoptera offer characteristics that help studies on behavior and phylogenetics. The objective of this study was to describe the adult male reproductive system of three Trypoxylon (Trypargilum) species. For that, tissues were disseced, fixed in 2.5% glutaraldehyde in 0.1 M sodium cacodylate buffer, pH 7.2 and postfixed in 1% osmium tetroxide. The material was dehydratated and embedded for light and electron transmission microscopes. The species have similar reproductive systems, which are formed by a pair of testes, each one with three fusiforme follicles, from which emerges an efferent duct that later joins forming a deferent duct. The deferent duct opens into an ejaculatory duct. The first half of the deferent duct is enlarged and differentiated in a region specialized in sperm storage, the seminal vesicle. The accessory gland flows in the post-vesicular region of the deferent duct. The testes and vesicles are both covered with a conjunctive capsule. Sexually mature individuals have all spermatogenesis stages in their follicles. Sperms are released from testes in bundles which are disorganized inside seminal vesicles.     

Developmental Expression of the Glucose Dehydrogenase Gene in Drosophila Melanogaster

The Gld gene of Drosophila melanogaster is transiently expressed during every stage of development. The temporal pattern of Gld expression is highly correlated with that of ecdysteroids. Exogeneous treatment of third instar larvae with 20-hydroxyecdysone induces the accumulation of Gld mRNA in the hypoderm and anterior spiracular gland cells. During metamorphosis Gld is expressed in a variety of tissues derived from the ectoderm. In the developing reproductive tract, Gld mRNA accumulates in the female spermathecae and oviduct and in the male ejaculatory duct and ejaculatory bulb. These four organs are derived from closely related cell lineages in the genital imaginal disc. Since the expression of Gld is not required for the development of these reproductive structures, this spatial pattern of expression is most likely a fortuitous consequence of a shared regulatory factor in this cell lineage. At the adult stage a high level of the Gld mRNA is only observed in the male ejaculatory duct.     

Imaginal pioneers prefigure the formation of adult thoracic muscles in Drosophila melanogaster

In insects, specialized mesodermal cells serve as templates to organize myoblasts into distinct muscle fibers during embryogenesis. In the grasshopper embryo, large mesodermal cells called muscle pioneers extend between the epidermal attachment points of future muscle fibers and serve as foci for myoblast fusion. In the Drosophila embryo, muscle founder cells serve a similar function, organizing large numbers of myoblasts into larval muscles. During the metamorphosis of Drosophila, nearly all larval muscles degenerate and are replaced by a set of de novo adult muscles. The extent to which specialized mesodermal cells homologous to the founders and pioneers of the insect embryo are involved in the development of adult-specific muscles has yet to be established. In the larval thorax, the majority of imaginal myoblasts are associated with the imaginal discs. We report here the identification of a morphologically distinct class of disc-associated myoblasts, which we call imaginal pioneers, that prefigures the formation of at least three adult-specific muscles, the tergal depressor of the trochanter and dorsoventral muscles I and II. Like the muscle pioneers of the grasshopper, the imaginal pioneers attach to the epidermis at sites where the future muscle insertions will arise and erect a scaffold for developing adult muscles. These findings suggest that a prior segregation of imaginal myoblasts into at least two populations, one of which may act as pioneers or founders, must occur during development.     

Apterous mediates development of direct flight muscles autonomously and indirect flight muscles through epidermal cues

Two physiologically distinct types of muscles, the direct and indirect flight muscles, develop from myoblasts associated with the Drosophila wing disc. We show that the direct flight muscles are specified by the expression of Apterous, a Lim homeodomain protein, in groups of myoblasts. This suggests a mechanism of cell-fate specification by labelling groups of fusion competent myoblasts, in contrast to mechanisms in the embryo, where muscle cell fate is specified by single founder myoblasts. In addition, Apterous is expressed in the developing adult epidermal muscle attachment sites. Here, it functions to regulate the expression of stripe, a gene that is an important element of early patterning of muscle fibres, from the epidermis. Our results, which may have broad implications, suggest novel mechanisms of muscle patterning in the adult, in contrast to embryonic myogenesis.     

Ultrastructure and function of the seminal vesicle of Bittacidae (Insecta: Mecoptera)

The fine structure of the seminal vesicle and reproductive accessory glands was investigated in Bittacidae of Mecoptera using light and transmission electron microscopy. The male reproductive system of Bittacidae mainly consists of a pair of testes, a pair of vasa deferentia, and an ejaculatory sac. The vas deferens is greatly expanded for its middle and medio-posterior parts to form a well-developed seminal vesicle. The seminal vesicle is composed of layers of developed muscles and a mono-layered epithelium surrounding the small central lumen. The epithelium is rich in rough endoplasmic reticulum and mitochondria, and secretes vesicles and granules into the central lumen by merocrine mechanisms. A pair of elongate mesodermal accessory glands opens into the lateral side of the seminal vesicles. The accessory glands are similar to the seminal vesicle in structure, also consisting of layers of muscle fibres and a mono-layered elongated epithelium, the cells of which contain numerous cisterns of rough endoplasmic reticulum and mitochondria, and a few Golgi complexes. The epithelial cells of accessory glands extrude secretions via apocrine and merocrine processes. The seminal vesicles mainly serve the function of secretion rather than temporarily storing spermatozoa. The sperm instead are temporarily stored in the epididymis, the greatly coiled distal portion of the vas deferens.     

Internal reproductive anatomy of the praying mantid Ciulfina klassi (Mantodea: Liturgusidae)

Using light and scanning electron microscopy, the internal male and female reproductive anatomy of the praying mantid Ciulfina klassi is identified and described. This is the first detailed study to investigate the internal reproductive morphology of any Mantodea. The female structures identified were (1) paired ovaries with primitive panoistic type ovarioles, (2) a single blind-ended spermatheca with secretory gland cells and surrounding layer of striated muscle, and (3) female accessory glands associated with the production of the ootheca (the egg casing). The male structures identified were (1) paired multi-tubular testes, in which different stages of spermatogenesis were observed, (2) tubular vasa deferentia, (3) seminal vesicles, (4) male accessory glands and (5) a single muscular ejaculatory duct. Knowledge of basic reproductive morphology can be used to infer function and so provide key information for future research into reproductive behavior and physiology in the Mantodea.     

The Vas Deferens of the Spanish Lobster,Scyllarus chacei

Summary

The male reproductive tract of Scyllarus chacei consists of paired testes and vasa deferentia that conduct sperm containing spermatophores to the genital pores at the base of each fifth walking leg. The testis is joined to the vas deferens which can be divided into four regions: (1) the anterior vas deferens can be further divided into three regions. It is highly convoluted and is the region in which the sperm become encapsulated in ovoid spermatophores of approximately 100 sperm as well as produces seminal fluids. (2) The middle vas deferens is the primary site of sperm storage and adds to seminal fluids which formed in the anterior region. (3) The posterior region is highly muscularized and may serve for limited sperm storage. (4) The most distal portion is the ejaculatory duct which is highly muscularized for extruding the spermatophoric mass for transfer to the female. A final seminar product is added here.     

Mode of formation of the flight muscles in a butterfly Pieris brassicae

The formation and development of the dorsal longitudinal flight muscles of the butterfly Pieris brassicae L have been studied by electron and light microscopy. These imaginal muscles arise from two symmetrical pairs of mesothoracic larval muscles, which are morphologically indistinguishable from the other wall muscles at the beginning of the 5th larval instar. However, 2 days before the end of this instar an accumulation of myoblasts is observed at the median region of these muscle fibres. The muscle fibres are penetrated by the myoblasts and broken into fragments. Progressive dedifferentiation of the larval fibrillar material in each of the muscle fragments is observed during the first days of the pupal development. The myoblasts within the basal lamina of the original larval muscle fibres remain associated with the muscle fragments. Myoblasts then fuse with the larval muscle fragments, which simultaneously fuse with each other. This results in the formation of rudimentary imaginal muscle fibres. The development of these fibres, particularly myofibrillogenesis, is studied until the emergence of the imago.     

The sperm roller: a modified testicular duct linked to giant sperm transport within the male reproductive tract

The male reproductive tracts of Drosophila display considerable variation in the relative size of their components, notably of the testes, but there are few structural differences between species. Here we report a remarkable coiled structure separating the testes from the seminal vesicles in the giant sperm species Drosophila bifurca. This evolutionary novelty, known as the 'sperm roller', seems to be an exaggeration in the size of the testicular duct as revealed by light and electron microscopic observations. It consists of a tubular monocellular epithelium lying on the basal laminae and muscle and conjunctive cells. The lumen of the roller contains crypts. The apical membrane of the epithelial cells presents numerous long microvilli protruding into the lumen. The sperm roller structure is probably involved in managing sperm during their transit through the male genital tract, because sperm are seen in bundles at the base of the testis, whereas they are singly rolled up by the time they enter the seminal vesicles. The hypercoiling of the individual spermatozoon within the roller probably occurs as the result of an osmotic process produced by features of the epithelial wall and the dramatically increased exchange surface. This is the first report of a specialized device of this type in Drosophila or, more generally, in insects.     

Differences in the Developmental Fate of Cultured and Noncultured Myoblasts When Transplanted into Embryonic Limbs

Myoblasts from embryonic, fetal, and adult quail and chick muscles were transplanted into limb buds of chick embryos to determine if myoblasts can form muscle fibers in heterochronic limbs and to define the conditions that affect the ability of transplanted cells to populate newly developing limb musculature. Myoblasts from each developmental stage were either freshly isolated and transplanted or were cultured prior to transplantation into limb buds of 4- to 5-day (ED4-5) chick embryos. Transplanted myoblasts, regardless of the age of the donor from which they were derived, formed muscle fibers within embryonic limb muscles. Transplanted cloned myoblasts formed muscle fibers, although there was little evidence that the number of transplanted myoblasts significantly increased following transplantation or that they migrated any distance from the site of injection. The fibers that formed from transplanted clonal myoblasts often did not persist in the host limb muscles until ED10. Diminished fiber formation from myoblasts transplanted into host limbs was observed whether myoblasts were cloned or cultured at high density. However, when freshly isolated myoblasts were transplanted, the fibers they formed were numerous, widely dispersed within the limb musculature, and persisted in the muscles until at least ED10. These results indicate that transplanted myoblasts of embryonic, fetal, and adult origin are capable of forming fibers during early limb muscle formation. They also indicate that even in an embryonic chick limb where proliferation of endogenous myoblasts and muscle fiber formation is rapidly progressing, myoblasts that are cultured in vitro do not substantially contribute to long-term muscle fiber formation after they are transplanted into developing limbs. However, when the same myoblasts are freshly isolated and transplanted without prior cell culture, substantial numbers of fibers form and persist after transplantation into developing limbs. Thus, these studies demonstrate that the extent to which transplanted myoblasts fuse to form fibers which persist in host musculature depends upon whether donor myoblasts are freshly isolated or maintained in vitro prior to injection.     

Cell lineage of the thoracic muscles of drosophila

The thorax of the adult Drosophila contains about 80 muscles, which develop from the mesoderm. A new genetic marker was used to map the cell lineage of the myoblasts that form these muscles. Clones of marked cells were produced by irradiation of embryos and larvae, and these were detected in the adult by histochemical staining. The principal findings are that the muscles of each segment have separate origins, and that each becomes compartmented precisely into a dorsal-lineage and a ventral-lineage set of muscles, each set probably being formed by the adepithelial cells found in one imaginal disc. In contrast with the epidermis, the muscles of each thoracic segment are not subdivided into anterior and posterior compartments, and clones of muscle cells that are homozygous for recessivelethal alleles of engralled develop normally.     

Observations on the ultrastructure of the copulatory organ of Archilopsis unipunctata (Fabricius, 1826) (Proseriata,Monocelididae)

The copulatory organ in adult specimens of Archilopsis unipunctata has been studied by transmission electron microscopy.This copulatory organ is of the conjuncta-duplex type with eversible cirrus. The seminal vesicle, lined with a nucleate epithelium, is surrounded by spirally arranged muscles. The fibres are enclosed in a sheath that is continuous with the septum of the bulbus and the basement lamina of the male canal epithelium. Distally to the seminal vesicle the bulbus is filled with the secretory cell-necks of the prostate glands. The male canal shows three different parts: seminal duct, ejaculatory duct and eversible cirrus. At the transition of seminal duct and ejaculatory duct two prostate ducts open into the lumen. The structure of the epithelium lining the different parts of the canal is described. The transition into the cirrus may be recognized by an abrupt change in the thickness, the electron density and the stratification in the basement lamina and by the disappearance of the epithelium absent indeed in the cirrus. The material found inside the cirrus-lumen is different according to the zone considered. The origin of this material and of the cirrus teeth is discussed.Abbreviations ab- apoptotic body - ba- bacteria - bb- basal bodies of cilia - bl- basement lamina - bw- body wall - c- cilia - cb- cell body - cgp- common genital porus - ci- cirrus - cip- cirrus plug - cl- lumen of cirrus - cm- circular muscles - cr- cytoplasmatic remnants - cs- cytoplasmatic sheets - ejd- ejaculatory duct - ep_ej- epithelium of ejaculatory duct - d- desmosomes - f- flagella of spermatozoa - fd- female duct - fp- female porus - gc- golgi complex - gl- glycogen particles - hd- hemidesmosomes - lm- longitudinal muscles - ly- lysosome-like body - m- muscles - m_b- muscles of the bulbus - m_c- muscles of the cirrus - m_c- muscles of the seminal vesicle - mi- mitochondria - ml- microvilli - ms- mesenchyme - n_sd- nuclei of the seminal duct - pd- prostate duct - pg- prostate glands - ri- ribosomes - s- septum - sb- secretory vesicle - sd- seminal duct - sp- spines - sv- seminal vesicle - v- vagina - vd- vas deferens     

Comparative morphology, homologies, and functions of the male system in oribatid mites (Arachnida: Acari)

The penis is basically a double-walled oval cone. The weak type penis (only 2 species) has a weak tongue, lacks a bridge, and is elongate. The strong type (all others) has a bridge, a strong tongue, thicker walls, and is short. An accessory gland and a common vas deferens always open into the inner cup lumen (= ejaculatory duct). The massive tongue muscles may open the penal orifice. A pair of penal retractor muscles originate on the body wall. Penal protrusion and perhaps partial extrusion of stalk substance is by hemolymph pressure. The penis is completely homologous to the ovipositor. The genital discs are cuticular cups containing glandular tissue and are retractible by muscles originating on the body wall. The minute, rod-like, immobile sperm are mixed with seminal fluid and stalk material secreted by seminal vesicle cells. This mixture is carried via the vase deferentia by peristalsis to the penis. Semen and stalk substance (protein) are somehow separated in the ejaculatory duct into separate pools, with stalk substance nearest the penal orifice. Upon penal protrusion, a bit of stalk material is extruded and fastened to the ground, and upon raising of the mite's body the stalk is “drawn out.” Finally, the ball of semen, adhering to the stalk tip, is pulled through the penal orifice.     

Ultrastructure of the copulatory organ of Haplopharynx quadristimulus and its phylogenetic significance (Plathelminthes,Haplopharyngida)

Summary The male reproductive system in Haplopharynx quadristimulus consists of paired testes, sperm ducts, seminal vesicles, seminal ducts, a copulatory organ containing prostatic vesicle and stylet apparatus, and the male canal. By electron microscopy all components appeared to be regional specializations of a canal extending from the testes to the body wall and lined by a multiciliated epithelium. The epithelium of the stylet apparatus contained six different cell types. One cell type (matrix syncytium) formed the stylet and the other five were located distal to the stylet/prostatic-vesicle junction along the male system epithelium. Each cell type was attached to the supporting intercellular matrix at a different level along the stylet apparatus. All cell types extended to the distal end of the stylet apparatus regardless of where they originated along its length. The cells in the apparatus lacked cilia, but one of the cell types contained rootlets. Modified rootlets or rootlet derivatives were possibly present in another cell type in the form of rootlet-like ribbons. The findings support the monophyly of the Macrostomida Haplopharyngida (by common occurrence of a matrix syncytium) and at the same time suggest their separation as two distinct taxa (by differences in the structure of the prostatic vesicle and other parts of the stylet apparatus).Abbreviations a accessory spine - c circular muscle - ce centriole - ci cilium - di dictyosome - e epithelial cell - ed ejaculatory duct - ep epidermal cell - f rootlet-like ribbon - g prostatic gland cell neck - g1 type I gland cell granules - g2 type II gland cell granules - g3 type III gland cell granules - h hemidesmosome - i intercellular matrix - im internal muscle - j septate junction - l stylet apparatus lumen - le spine lateral extension - lm longitudinal muscle - m matrix syncytium - mc male-canal epithelial cell - me male canal - mp male pore - mt microtubules - mv microvilli - n nucleus - nc nerve cell body - np nerve process - om oblique muscle - p prostatic vesicle epithelial cell - pv prostatic vesicle - r rootlet - s stylet - sa stylet apparatus - sc sensory receptor - sd sperm duct - se seminal duct - sl stylet lumen - sp spot desmosome - sr sperm - sv seminal vesicle - t terminal web - te testis - u ultrarhabdite - z zonula adhaerens - 2 cell type 2 - 3 cell type 3 - 4 cell type 4 - 6 cell type 6     

Testosterone concentration in testicular venous blood of adult rats and seminal citric acid and fructose concentration as well as weight of accessory sex organs.

In 31 adult rats of Wistar strain (body weight 231 +/- 14g) the relationships between testosterone concentration in testicular venous blood of an individual rat and weight of accessory sex organs (testes, seminal vesicles, ventral prostate, levator ani muscle) and citric acid and fructose concentrations in seminal vesicles were investigated. No direct relationship was found between testosterone concentration and the above parameters. The correlation coefficient varied from 0.042 to 0.394.