Excretion in the house cricket (Acheta domesticus): fine structure of the Malpighian tubules

An ultrastructural analysis of the Malpighian tubules of the cricket, Acheta domesticus, is presented. The excretory system of the cricket is unusual in that the 112 Malpighian tubules do not attach directly to the gut, but fuse to form a bladder-like ampulla which is joined to the colon by a muscular ureter. The tubules have three structurally distinct segments and consist of four cell types. Attached by basal lamina to the outer surface of the distal tip are nodules, consisting of small cells on membranous stalks. These are presumed to serve as attachments to the body wall. The distal 20% of the tubule is hyaline, consisting of a monolayer of squamous cells that appear to be secretory. The mid-tubule comprises 75% of the total length and is the primary region for fluid secretion. It is also characterized by having large numbers of laminate spheres in the cytoplasm of the cells. The proximal 5% of each tubule consists of more columnar cells and may function in fluid resorption. The relationship between structural features and known physiological functions are discussed.     

The structure of the excretory system of the infective larva of Haemonchus contortus

The excretory system of the infective larva of Haemonchus contortus consists of a tubular H-system with two excretory cells. The excretory cells contain electron-dense granules which may be a source of exsheathing fluid. Video microscopy indicates that the pulsation of the excretory ampulla is due to a cycle of filling and emptying controlled by the excretory valve. The apparent functional similarity between this system and the contractile vacuole complex of protozoa is discussed.     

The phylogenetic distribution of the ampulla ureter and ampulla urogenital/uriniferous papilla in the Serpentes

The ampulla ureter and ampulla urogenital/uriniferous papilla represent differing morphologies of the caudal urogenital ducts in snakes. The ampulla ureter is an enlarged portion of the caudal extremity of the ureter that communicates the cranial regions of the ureter and the ductus deferens/Wolffian duct to the urodaeum. The ampulla urogenital/uriniferous papilla is an enlarged pouch, distinct from the ureter, which communicates the ureter and ductus deferens/Wolffian duct to the urodaeum. Although functional differences of these two structures are unknown, the ampulla urogenital/uriniferous papilla may have evolved for urine storage in males and females, and secondarily evolved a reproductive function in males. The most parsimonious optimization of the ampulla ureter and ampulla urogenital/uriniferous papilla indicates that the ampulla ureter is the ancestral state in snakes. Examining the presence or absence of the ampulla ureter and ampulla urogenital/uriniferous papilla in snakes on conflicting caenophidian phylogenies results in two hypotheses for the evolution of these variant morphologies: (1) The ampulla urogenital/uriniferous papilla evolved from the ampulla ureter independently in the Colubroidea and Elapoidea with subsequent losses of the ampulla urogenital/uriniferous papilla in the Elapoidea and (2) a single transition from the ampulla ureter to the ampulla urogenital/uriniferous papilla on the branch leading to the Colubroidea + Elapoidea with subsequent losses of the ampulla urogenital/uriniferous papilla in the Elapoidea and Colubroidea. The presence of the ampullae urogenital/uriniferous papilla in only the Colubroidea and Elapoidea highlights the affinity of these two taxonomic groups, a relationship that is strongly supported in published cladograms produced with molecular datasets.     

Scanning and transmission electron microscopic observations of the cloacal epithelia of the domestic fowl

Summary The epithela of the three divisions (coprodaeum, urodaeum, proctodaeum) of the cloaca of the hen, and of the excretory ducts (colon, ureter, vagina) which join the divisions, are described using light microscopy, and scanning and transmission electron microscopy. Each region of the cloaca has its typical epithelium. Special attention is focussed in this study on the boundaries between the different epithelia. The coprodaeal epithelium does not differ considerably from that of the colon; a transitional zone is not visible. Distinct border zones, however, are observed between the other regions (ureter — urodaeum; vagina — urodaeum and proctodaeum; urodaeum-proctodaeum; proctodaeum — cutis). Although the vaginal opening is generally thought to lie in the urodaeum, our investigations show that at the vaginal opening into the cloaca the ciliated epithelium changes, on one border to a secretory epithelium characteristic of the urodaeum and on the other border to that characteristic of the proctodaeum. These observations are discussed in relation to functional aspects.     

Morphology and function of Malpighian tubules and associated structures in the cockroach, Periplaneta americana.

This paper describes the different regions of the Malpighian tubules and the associated structures (ampulla, midgut, ileum) in the cockroach, Periplaneta americana. There are about 150 tubules in each insect. Each tubule consists of at least three parts. The short distal region is thinner than the other parts and is highly contractile. The middle region comprises most of the tubule length and is composed of primary and stellate cells. Primary cells contain numerous refractile mineral concretions, while stellate cells have smaller nuclei, fewer organelles, simpler brush border, and numerous multivesicular bodies. Symbiont protozoa are sometimes present within the lumen of the middle region near where it opens into the proximal region of the tubule. The latter is a short region that drains the tubular fluid into one of the six ampullae. These are contractile diverticula of the intestine located at the midgut-hindgut junction. The ampulla is highly contractile, and consists of a layer of epithelial cells surrounding a cavity that opens into the gut via a narrow slit lined by cells of unusual morphology. The proximal region of the tubule and the ampulla resemble the midgut in that they have similar micromal origin and reabsorptive function for the proximal region of the tubule and for the ampulla. A number of inclusions found within the tubule cells are described, including peroxisomes and modified mitochondria. Current theories of fluid transport are evaluated with regard to physiological and morphological characteristics of Malpighian tubules. The possible role of long narrow channels such as those between microvilli and within basal folds is considered, as is the mechanism by which these structures are formed and maintained. Also discussed is the role of peroxisomes and symbionts in the excretory process.     

THE MECHANISM OF THE NEPHRIDIAL APPARATUS OF PARAMECIUM MULTIMICRONUCLEATUM : II. The Filling of the Vesicle by Action of the Ampullae

Our recent analysis of the nephridial apparatus of Paramecium multimicronucleatum by high-speed cinematography (300 fps at X 250) indicates that before the water expulsion vesicle ("contractile vacuole") is completely voided of fluid during expulsion, the ampullae surrounding and confluent with the vesicle swell with fluid entering from their respective nephridial tubules. Once the membranes of the excretory pore at the base of the excretory canal (leading from the vesicle proper to the outside) have constricted and resealed the excretory pore, the up till then constricted injection tubules of the ampullae which conduct fluid to the vesicle open as waves of contraction along the coacervate gel around the ampulla and proceed along each ampulla from distal to proximal end. The coacervate gel around any one ampulla does not necessarily contract in phase with that of any other ampulla. Each ampulla acts independently. The fluid from the ampullae is thus pumped sequentially, but not in predetermined order, into the water expulsion vesicle, refilling and distending it. Our previous studies (Organ et al., 1968a) suggest that an actomyosinoid ATP-using mechanism may be functional in the ampullary contractions.     

Functional anatomy of the valves in the ambulacral system of sea urchins (Echinodermata,Echinoida)

Summary The water vascular system of sea urchins is examined with special reference to the valves positioned between the radial vessel and the ampullae of the tube feet. The lips of the valve protrude into the ampulla. Thus the valve functions mainly like a check valve that allows the unidirectional flow of fluid towards the ampulla. Each ampulla-tube foot compartment acts as a semi-autonomous hydraulic system. The lumina of the ampulla and the tube foot are lined with myoepithelia except for the interconnecting channels that pierce the ambulacral plate. The contraction of the ampulla results in an increasing hydraulic pressure that protrudes the tube foot, provided that the valve is closed. The retraction of the tube foot results in a backflow of fluid independent of the condition of the valve. The lips of the valve are folds of the hydrocoel epithelium. The pore slit lies in the midline. The perradial faces of the lips are covered with the squamous epithelium of the lateral water vessel. The ampullar faces are specialized parts of the ampulla myoepithelium. Turgescent cells which form incompressible cushions take the place of the support cells. The valve myocytes run parallel to the pore slit and form processes that run along the base of the ampulla and the perradial channel up to the podial retractor muscle. The findings lead to the hypothesis of multiple control of the ampulla-tube foot system: (1) The mutual activity of the ampulla and the tube foot is indirectly controlled by the lateral and podial nerves which release transmitter substances that diffuse through the connective tissue up to the muscle layers. (2) A muscle-to-muscle conduction causes the simultaneous contraction of the ampulla or the podial retractor muscles. (3) The valve muscles are directly controlled by the processes of the valve myocytes which make contact with the podial retractor. In extreme conditions a backflow of hydrocoel fluid towards the radial water vessel occurs.     

Ricerche istochimiche e al micro scopio elettronico sui tubi malpighiani di Dacus oleae Gmel.

Summary The Dacus oleae larva possesses four Malpighian tubules, two anterior and two posterior ones, which in pairs enter into a ureter. Before opening into the gut, at the level of the transition zone between the mid- and hindgut, each ureter is dilated into an ampulla.The anterior tubules are divided into four regions: distal, transition, middle and proximal ones: while in the posterior tubules only middle and proximal segments are detectable. The distribution of the enzyme systems is indicated in Fig. 3, while the ultrastructural organization which is typical of the cells composing the different regions is schematically represented in Fig. 1. According to the ultrastructural and enzymatic findings, and the discussion on this subject in the literature, the authors are led to assume that in the distal segment occurs the segregation of uric acid, urates and calcium salts. In the transition segment, and still more in the intermediate one, an indiscriminate transport of water and solutes occurs from the haemocoel into the lumen of the tubule by pinocytosis. A fraction of the catabolites is precipitated as chromolipoidal pigments. The transition stages between cytosomes and pigment are described. Along with secretory phenomena the resorption of useful substances occurs in the proximal region. A similar function is performed by the ureter. In the ampulla, which is characterized by a conspicuous system of deep tubular infoldings both at the apical and basal surfaces of its cells, a massive water resorption is presumed to occur.     

Ultrathin structure of the main lateral nerve cords and accompanying elements of Triaenophorus nodulosus (Cestoda: Pseudophyllidea)

The ultrastructure of lateral nerve cords (LNC) of Triaenophorus nodulosus has been studied. 4 of the 6 types of neurones earlier reported for cerebral ganglia are present in LNC: multipolars, bipolars, unipolars and "light"; neurosecretory cells of the 7th type lie in transverse commissures. The growth and formation of LNC occur at the expense of undifferentiated cells found on the cord periphery among mature neurones. LNC are surrounded with specialized envelopes made of cell processes of excretory vessels and a fibrillar matrix formed at early stages of cestode development. In large axons, cisternae of the cross reticulum are detected, which can serve as ultrastructural marker of the synapse. Two types of muscle innervation are determined. The direct innervation of muscular fibres is realized by peripheral neurosecretory neurones, which form contacts of the paracrine type. The central or sarco-neural innervation of muscular fibers occurs in LNC via the entering muscular processes.     

Localization of a Drosophila DRIP-like aquaporin in the Malpighian tubules of the house cricket, Acheta domesticus

Malpighian tubules (Mt) are the primary excretory and osmoregulatory organs of insects, capable of rapidly transporting extraordinary volumes of fluid when stimulated by diuretic factors. In the house cricket, Acheta domesticus, the Mt are composed of three morphologically distinct regions (proximal, mid, and distal). Unlike the dipteran Mt, which have both primary and stellate cells, each region of the Acheta Mt consists of a morphologically uniform cell type. The mid and distal regions are both secretory in function and increase secretion rate in response to dibutyryl cAMP (cAMP). Achetakinin-2, while acting synergistically with cAMP on the mid-Mt, inhibits secretion by the distal Mt, and the effects can be reversed by cAMP. Using an antibody to the water-specific Drosophila aquaporin (DRIP), we demonstrated that DRIP-like immunoreactivity was found in both the distal and mid-Mt. The distribution of the aquaporin altered in response to stimulation and was consistent with the secretory data. The regulation of secretion in Acheta Mt is quite different from that of Drosophila, with both cation and anion/water transport occurring in the same cells. This is the first demonstration of the presence of an insect aquaporin, namely DRIP, in the Mt of an order other than the Diptera.     

Morphology of the foveal glands and foveae dorsales in male Hyalomma truncatum and Rhipicephalus evertsi mimeticus ticks (Acari; Ixodidae) before and during feeding

The ultrastructure of the foveae dorsales and foveal glands in unfed and attached male Hyalomma truncatum and Rhipicephalus evertsi mimeticus ticks was studied. Both species are provided with a paired foveal gland system, which is similar in unfed as well as in attached ticks. This gland system consists of the fovea dorsalis with pores and pore tubes as the external part, the foveal neck zone as a link between the fovea dorsalis and the lobes of the gland and the bulbous lobes as the innermost part. The fovea dorsalis is located on either side of the dorsal midline in the midsection of the body and appears as a roundish plate containing 15±6.5 and 21±7 slit-like pores in R. evertsi mimeticus (n=210) and H. truncatum (n=210), respectively. Each pore leads into a cuticular lined channel containing a pore tube. Below each fovea, the foveal neck zone is located within a groove of the cuticle and consists of the termini of the pore tubes which enlarge basally to form a cup-shaped ampulla each. Furthermore, secretory lobes are located below the foveal neck zone. Each lobe consists of secretory cells and a central excretory duct which leads into the ampulla. The ducts are lined with microvilli. The secretory cells contain numerous vesicles of varying size with one or more granules. In male ticks of both species the secretory lobe cells remained unchanged in size, structure and granule content irrespective of whether they were unfed or attached for up to 30 days. Axons occur in the fascicles between the secretory lobe cells containing numerous neurosecretory vesicles. A possible role of the foveal glands in the production of pheromones is hypothesized.     

Histoarchitecture of the human parotid duct. Light-microscopic study

A light-microscopical study of the histoarchitecture of the human parotid duct was carried out. The parotid duct, much like other excretory passages, possessed three histological coats: mucosa, muscular layer and adventitia. The mucous epithelium was composed of the innermost tall columnar cells and the basal cubical cells. Numerous, circular elastic fibers were in close vicinity to the epithelium. The muscular layer consisted of smooth muscular fibers running in longitudinal direction. The adventitia consisted of lipofibrous connective tissue and contained many vessels. The result of the present study suggests that the parotid duct contributes to control of salivary secretion, since its architecture is basically similar to that of other excretory passages which have peristaltic activity.     

Reproductive morphology of the male Tuatara,Sphenodon punctatus

Over the past decade, studies on reproductive morphology in the Squamata (snakes and lizards) have expanded tremendously. With the accumulation of these studies and revisions of the terminology based on structural similarities and differences, it is imperative to review the work on tuataras to determine whether the structural organization fits the revised terminology of vertebrates. We investigated the morphology of the male reproductive system in the Tuatara, Sphenodon punctatus (Rhynchocephalia), the sister taxon to the Squamata. Previous studies on the Tuatara used a nomenclature for the testicular ducts different from the current terminology for amniotes. The reproductive system in the Tuatara is consistent with reports in the Squamata. Two rete testis tubules exit the testis within a connective tissue sheath similar to that shown in other squamate species and the protherian Echidna. Each rete testis divides into multiple ductuli efferentes that fuse with the epididymis. The epididymis transitions into the ductus deferens where the sperm become more concentrated into spherical bundles. The ductus deferens enters the cloacal urodeum separately from the ureter. An ampulla ureter or ampulla urogenital papilla was not observed, which differs from previous studies of lepidosaurians. Furthermore, a sexual segment of the kidney (SSK) was not observed, consistent with previous studies on the Tuatara.     

Anatomy of the cecum of the gerbil Meriones unguiculatus (Mammalia,Rodentia, Cricetidae)

Summary The macroscopic and microscopic anatomy of the cecum of the gerbil was investigated using dissections, dried specimens and vascular injections as well as light-, scanning- and transmission electron microscopy.The cecum of the gerbil is a voluminous organ, possessing slight sacculations and only poorly developed taeniae. The base or ampulla ceci is slightly dilated and more voluminous than the corpus ceci, which decreases gradually in diameter to the blind-end, the apex ceci. A half ring-fold limits the entrance to the proximal colon from the ampulla. A wide-opened communication exists between ampulla and corpus ceci. The scanning microscopical appearance of the cecal wall takes the form of raised elevations circumventing a central depression. The cecum is lined internally by a tall columnar epithelium displaying a well-developed microvillar border and possessing numerous cellular organelles.     

Pharmacology of ureter.

Ureter which performs the important function of transport of urine from kidney to the bladder is not a passive tube, but exhibits characteristic spontaneous (peristaltic) activity. This peristaltic activity is characterized by coordinated muscular contractions, which after originating from a spontaneously active primary pacemaker, situated in the vicinity of the pelvi ureteric junction, propagate downwards along the entire length of the ureter. In addition, the ureter, like the heart, possesses certain cells which become activated when the primary pacemaker is suppressed or there is an interruption of conduction, thereby, acting as latent pacemakers. (1) The peristaltic activity of the ureter is modified by several pharmacologically active substances. Moreover, some of these substances are occasionally able to initiate spontaneous activity even in quiescent ureters. This article briefly reviews the effects of catecholamines (adrenaline, noradrenaline and isoprenaline) and acetylcholine on the ureters of human beings and some domestic and laboratory animals.     

Expression of villin in the mouse oviduct and the seminiferous ducts

Summary Villin, a 95-kD cytoskeletal protein selectively expressed in the microvilli of some absorptive cells was localized immunohistochemically in the oviduct and the seminiferous excretory ducts of the mouse. Villin was found in the proximal part of the oviduct, comprising the preampulla, ampulla, and part of the isthmus. Distal to the isthmus the oviductal cells lining the junctura and the intrauterine colliculus tubaris were devoid of villin. No villin could be detected in the uterine cells.Ductuli efferentes, connecting the rete testis with the epididymis were the only portion of the male seminiferous ductal system expressing villin. The cells lining the epididymis and the vas deferens were devoid of villin. These data show that villin is selectively expressed in male and female reproductive systems and that it is limited to anatomically defined proximal portions of the reproductive ducts.     

On the mechanism of prometaphase congression: Chromosome velocity as a function of position on the spindle

Rates of movement of univalents at prometaphase and of half-bivalents at anaphase in living cricket and grasshopper spermatocytes were determined as a function of the distance from the pole toward which the movement was directed. In the artificially produced univalents of cricket cells, correlation coefficients for rate versus distance form the pole were widely disparate from movement to movement and there was no consistent relationship between velocity and distance from the pole. However, in the naturally occurring univalents of grasshopper cells, there was a significant positive correlation between velocity and distance from the pole. In both cricket and grasshopper cells, there was no consistent correlation between rate of movement and distance from the pole for half-bivalents at anaphase. The prometaphase data from grasshopper cells support the simple hypothesis of Östergren (1950) that congression results from the application to chromosomes of forces which increase with increasing distance from the pole. Furthermore, these data are consistent with models of force production which suppose that the relationship between force (reflected as velocity) and distance from the pole is a linear one.     

Electron-microscopic study of the excretory system of hungry females of the tick Hyalomma asiaticum P. Sch. et E. Schl. 2]

In H. asiaticum the cells of the Malpighian tubules and these of the rectal cas have the uniform structure: the apical surface is covered with microvilli, the basal plasmatic membrane forms relatively small invaginations. As to ultrastructural characters, there is no distinct division of the Malpighian tubule into departments. The distal ends of the tubules are not only somewhat enlarged and form the so-called ampulla cells of which are noticeably flattened. The microvilli and basal folds of the plasmatic membrane in this area of the tubule are indistinct. The cells of the ampulla and the neighbouring area of the tubule are characterized by the presence of inclusions with mucopolysaccharide secretion confined by the membrane. The microvilli are most developed on cells of the proximal ends of the Malpighian tubules. Well developed microvilli of the rectal sac form a striated border each containing a microtube inside. The basal invaginations are developed here better than in the cells of the Malpighian tubules.     

Early innervation of the metanephric kidney

During kidney differentiation, the nephrogenic mesenchyme converts into renal tubules and the ureter bud branches to form the collecting system. Here we show that in the early undifferentiated kidney rudiment there is a third cell type present. In whole-mount preparations of cultured undifferentiated metanephric kidneys, neurones can be detected by immunohistochemical means with antibodies against the neurofilament triplet, 13AA8, and against neuronal cell surface gangliosides, Q211. Clusters of neuronal cell bodies can be seen in the mesenchyme close to the ureter bud. The terminal endings of neurites are found around the mesenchymal condensates that later become kidney tubules. A similar distribution of neurites can be revealed in tissue sections of kidney grafts growing in the chicken chorioallantoic membranes. In primary cultures of the ureter bud cells, neurones are constantly present. In another report, we have shown that, in experimental conditions, neurones are involved in regulation of kidney morphogenesis. The present results raise the possibility that neurones of the metanephric kidney may have this function in vivo as well.