Organogenesis in the leech: development of nephridia,bladders and their innervation

The formation of the definitive excretory system (nephridium and bladder complex) in Hirudo medicinalis during the last two thirds of embryonic development was observed with light- and electron microscopy, immunocytochemistry, and nuclear labeling. In jawed leeches, two excretory systems develop and function successively. The nephridia of the cryptolarva are associated with the larval sac and persist until the definitive nephridia are sufficiently developed to be functional. Development of the definitive excretory system begins with the differentiation of the (ectodermal) bladder and urethra. The cells from which they arise incorporate bacteria and are thereby recognizable at day 8. The (mesodermal) urine-forming tissues of the nephridium (canalicular cells and central canal cells) appear a day later. By day 17, the nephridia are in contact with the outlet region and structurally able to function. Each nephridium is individually innervated by a peripheral neuron, the nephridial nerve cell, which expresses FMR Famide-like immunoreactivity and begins growing into the nephridium on day 11. Organogenesis of the leech nephridium is compared with the formation of excretory organs in other species. The temporal correlation of innervation and the development of the transporting cells is discussed. Correspondence to: A. Wenning     

Ultrastructure and significance of the transitory nephridia in Erpobdella octoculata (Hirudinea, Annelida)

In early developmental stages of Erpobdella octoculata two pairs of transitory nephridia occur which degenerate during the formation of the body segments. Because in the ground pattern of Annelida the first nephridia formed during ontogenesis are protonephridia, it can be assumed that the transitory nephridia of E. octoculata are homologous to the larval protonephridia (head kidneys) of Polychaeta. To test this hypothesis two cryptolarvae of E. octoculata were investigated ultrastructurally. Both pairs of transitory nephridia are serially arranged to either side of the midgut vestigium. Each organ consists of a coiled duct that opens separately to the exterior by an intraepidermal nephridiopore cell. The duct is percellular and formed by seventeen cells. Adluminal adherens and septate junctions connect all duct cells; the most proximal duct cell completely encloses the terminal end of the duct lumen. A filtration structure characteristic for protonephridia is lacking. Additionally, the entire organ lacks an inner ciliation. Morphologically and ultrastructurally the transitory nephridia of E. octoculata show far reaching congruencies with the segmental metanephridia in different species of the Hirudinea. These congruencies support the assumption that formation of transitory nephridia and definitive metanephridia in Hirudinea depends on the same genetic information. The same inherited information is assumed to cause the development of larval head kidneys and subsequently formed nephridia in different species of the Polychaeta. Thus, the presumed identical fate of a segmentally repeated nephridial anlage supports the hypothesis of a homology between the transitory nephridia in Hirudinea species and the protonephridial head kidneys in the ground pattern of the Polychaeta. We, therefore, assume that functional constraints lead to a modification of the protonephridial head kidneys in Hirudinea and explain ultrastructural differences between the transitory nephridia in Hirudinea and the protonephridia in Polychaeta. Accepted: 11 December 2000     

The anatomy and histology of the nervous system and excretory system of the maldanid polychaetes Clymenella torquata and Euclymene oerstedi

The nervous system of the maldanid polychaetes Clymenella torquata (Leidy) and Euclymene oerstedi (Claparede) (= Caesicirrus neglectus [Arwidsson, '11-'12]) retains its primitive association with the epidermis. It shows only slight metamerism in the presence of larger collections of neurones opposite the parapodia and of larger nerves at the segmental boundaries. Multicellular giant fibers are present in the ventral nerve cord; giant neurones which show a characteristic pattern of distribution in each species are also present. The cerebral ganglia supply nerves to the prostomial wall, nuchal grooves and the wall of the buccal cavity, and a pair of large nerves from the circumpharyngeal connectives also appear to join the buccal system. The organs of special sense are the elongated prostomial nuchal grooves, and prostomial ocelli in Euclymene but not in Clymenella. Statocysts are absent. Four pairs of nephromixia are present. They lie in the aseptate anterior trunk, in chaetigers 5–9 of Clymenella, and 6–10 of Euclymene. The nephridiopores lie at the ventral ends of the neuropodia of chaetigers 6–9 and 7–10, respectively. Each nephromixium consists of coelomostome, tubule and contractile bladder. The wall of the tubule and bladder consists of both excretory and ciliated cells. Most of the cytoplasm of the latter forms a bounding layer at the outer surface. The cytoplasm of the excretory cells contains lipid material and appears to synthesize lipofuscin. The tips of the excretory cells swell, fill with granules, and break off in the form of vesicles which are periodically expelled in clouds from the nephridiopores. Glycogen is present, especially in the ciliated cells of the tubule and coelomostome. Granules of a lipoid nature accumulate in (or between) cells of the nephridia, epidermis, and some regions of the gut, and may be excretory. Lipid granules also appear to be synthesized by coelomocytes which eventually end up in masses in the ventrolateral coelomic cavities of the tail. The nephridia act as gonoducts, but show no seasonal variation in either size or histological structure.     

6-Keto-prostaglandin F1 alpha is not added to urine during passage through the rat urinary bladder in vivo

Studies were conducted to determine whether prostaglandins are added to the urine during its passage through the rat urinary bladder in vivo. Control rats and rats with chronic streptozotocin-induced diabetes were anesthetized with Inactin, 100 mg/kg i.p., and urine was collected simultaneously from both kidneys. Urine from the left kidney was collected directly from the renal pelvis via a ureteral cannula, while urine from the right kidney was collected via a cannula in the urinary bladder. Prostaglandins in the urine were measured by radioimmunoassay. No difference in urinary concentration or rate of excretion of 6-keto-PGF1 alpha or PGE2 was seen between ureteral urine and bladder urine from either normal or diabetic rats. The results of this study indicate that in vivo there is no intralumenal addition of either 6-keto-PGF1 alpha or PGE2 to the urine by the ureteral bladder of rats.     

6-keto-prostaglandin F1α is not added to urine during passage through the rat urinary bladder

Studies were conducted to determine whether prostaglandins are added to the urine during its passage through the rat urinary blader . Control rats and rats with chronic streptozotocin-induced diabetes were anesthetized with Inactin, 100 mg/kg i.p., and urine was collected simultaneously from both kidneys. Urine from the left kidney was collected directly from the renal pelvis via a ureteral cannula, while urine from the right kidney was collected via a cannula in the urinary bladder. Prostaglandins in the urine were measured by radioimmunoassay. No difference in urinary concentration or rate of excretion of 6-keto-PGF_1α or PGE₂ was seen between ureteral urine and bladder urine from either normal or diabetic rats. The results of this study indicate that there is no intralumenal addition of either 6-keto-PGF_1α or PGE₂ to the urine by the ureteral bladder of rats.     

Structure of the nephridium in Ophryotrocha puerilis (Polychaeta,Dorvilleidae)

Summary The nephridia of Ophryotrocha puerilis are segmental organs. The nephrostome opens at the posterior margin of a setigerous segment into the coelomic cavity of this segment. The nephridial canal is made up of about 15 cells. These cells form an S-shaped tubule which extends into the following segment. The lumen of the nephridial canal ranges from 2 to 7 m in diameter. The nephropore opens laterally on the ventral surface of the body wall.In cross sections, one, two, or three cells are seen forming the canal. The inner surfaces of the canal cells are of different appearances along the canal. Since no regular pattern of cell distribution was found along the canals of different nephridia it is assumed that changes in cell structure along the canal are due to functional states or properties rather than to anatomically fixed regional differences. The canal cells either show smooth contours or they form brush borders of microvilli or sponge-like inner surfaces with a system of vacuolar canals running through the cytoplasm. Most of the canal cells are filled with various kinds of vesicles. Usually two or three cells contain larger vesicles up to 2.5 m in diameter with more or less electron-dense contents. Some of these vesicles resemble lysosomes. There are at least three bundles of cilia in each canal. In young specimens the number of cilia in one bundle is smaller (10–15) than in adult specimens (60–70). The nephridia do not show sex specific differences. The female nephridia do not function as genital ducts. As judged from the sizes of sperm and nephridia it appears to be possible that sperm are shed via male nephridia.     

Studies on urine and tissues of rats,guineapigs and mice exposed to sulphur mustard using mass spectrometry

Urine and tissues (brain, liver, kidney, fat and triceps muscles) from rodents (rats, guinea pigs and albino mice) treated with sulphur mustard percutaneously were examined for the presence of sulphur mustard and/or metobolites using electron impact direct inlet and GC-mass spectrometry. Sulphur mustard and thiodiglycol sulphoxide were not detected in these samples even after application of massive doses. However, thiodiglycol was identified in urine only     

Ultrastructure of the male nephridium and its role in spermatophore formation in spionid polychaetes (Annelida)

Summary The mature male nephridia ofPolydora ligni andP. websteri (Polychaeta: Spionidae) are segmental organs composed of a ciliated nephrostome connected to a nephridial canal that crosses the intersegmental septum, expands into a large modified part extending dorsally through the coelom and subsequently narrows into a canal terminating in a dorsal nephridiopore. The nephridial canal is ciliated throughout and is composed of several cell types. Cells in the expanded region of the nephridia of both species contain large urn-shaped depressions filled with long microvilli. InP. ligni, one section of a nephridium contains cells packed with electron-dense granules that are not observed inP. websteri.The spermatophores ofPolydora ligni are composed of a central sperm mass surrounded by a layer of randomly oriented tubules that form a capsule around the sperm and taper into a long thin tail. These tubules are identical in dimensions to the microvilli present in parts of a nephridium and apparently are derived from these microvilli. The spermatophore capsule ofP. websteri is composed of similar tubules also presumed to originate from nephridial microvilli.The microvilli in nephridia of both species are surrounded with a glycocalyx that may function as an adhesive to hold the spermatophore capsule together. This glycocalyx may also function as a species specific message when encountered by a receptive female.Contribution Number 179 from Harbor Branch Foundation, Inc.     

Structure and development of the nephridia of Tomopteris helgolandica (Annelida)

 Nephridial diversity is high in Phyllodocida (Annelida) and ranges from protonephridia to metanephridia. The nephridia of Tomopteris helgolandica (Tomopteridae) can be characterized as metanephridia which bear a multiciliated solenocyte. This cell is medially apposed to the proximal part of the nephridial duct and bears several cilia, each of which is surrounded by a ring of 13 microvilli. An extracellular matrix connects the microvilli and thus leads to the impression of a tube surrounding the central cilium. Each tube separately enters a subjacent duct cell and the cilia extend into a cup-shaped compartment within the duct cell. This compartment is not connected to the duct. The funnel consists of eight multiciliated cells and is connected to the nephridial duct, which initially runs intercellularly and later percellularly. The last duct cell bears a neck-like process which pierces the subepidermal basal membrane and is connected to epidermal cells forming a small invagination, the nephropore. The nephridia of T. helgolandica develop from a band of cells and all structural components are differentiated at an early developmental stage. Further development is characterized by enlargment of the funnel, ciliogenesis in the solenocyte, merging of different sections of the duct and, finally, the formation of the nephropore. An evaluation of the nephridia of T. helgolandica leads to the hypothesis that the nephridial diversity in Phyllodocida can be explained by the retainment of different stages in the transition of protonephridia into metanephridia; this is caused by the formation of a ciliated funnel at different ontogenetic stages. Although the protonephridia in Phyllodocida are regarded as primary nephridial organs, protonephridia are also presumed to have evolved secondarily in progenetic interstitial species of the Annelida by an incomplete differentiation of the nephridial anlage. Accepted: 18 December 1996     

Morphology and ultrastructure of the nephridial system of Hypania invalida (Grube, 1860) (Annelida,Polychaeta, Ampharetidae)

The excretory organs of the freshwater polychaete Hypania invalida have been examined using scanning and transmission electron microscopy. Three pairs of macroscopically and ultrastructurally different nephridia are present in the thorax. Intersegmental septa in the thorax are absent, with the exception of a single diaphragm between second and third chaetiger. The first pair of nephridia is anterior to this septum, the second pair crosses the septum, with the nephrostomes anterior and the ducts and the nephridiopori posterior to it, and the third pair of nephridia is entirely posterior to the diaphragm. The first two pairs of nephridia have ciliated nephrostomes of moderate size and long nephridial ducts that extend the length of the thorax. In contrast, the third pair is characterized by short ducts and very prominent nephrostomes. Macroscopically, seven different sections of nephridial duct cells can be distinguished along the length of the first two pairs of nephridia, whereas, on an ultrastructural basis, only six different regions can be identified. Only two regions of different duct cells can be recognized in the third pair of nephridia. Cells of the two anterior pairs of nephridia show typical characteristics of transport epithelia and most likely function as excretory organs. In contrast, the duct cells of the third pair are not that much differentiated and might primarily be responsible for the release of sexual products, as sperm was observed passing through these ducts. Podocyte‐like cells were observed to accompany nephridial ducts. J. Morphol., 2011. © 2010 Wiley‐Liss, Inc.     

Cytology of lleal conduit urine in bladder cancer patients: diagnostic utility and pitfalls

OBJECTIVE: To study the cytomorphology of urine obtained from the ileal conduit and to determine its utility and identify the pitfalls. STUDY DESIGN: Urine specimens from 469 cases of suspected or proven bladder cancer received over a period of 5 years were analyzed in the cytology laboratory. In 35 cases, total bladder resection was followed by ileal conduit reconstruction. The follow-up cytologic analysis of these 35 ileal conduit cases formed the basis of this study. RESULTS: There was absence of urothelial cells in all but 2 cases. The smear predominantly showed small, scattered intestinal mucosal cells with pyknotic nuclei, extensive karyorrhexis and numerous bacteria. In 2 cases, cytology proved superior to endoscopy and radiology in detecting recurrent disease. We had 2 false negative cases, and the negativity was attributed to sampling errors. There was 1 false positive case in which 3-dimensional clusters of intestinal columnar cells were erroneously diagnosed as adenocarcinoma. CONCLUSION: Urine obtained from ileal conduit specimens shows a smear picture that is different from that of specimens from the bladder. Thus, it is imperative to understand the difference between the cytomorphology of bladder urine and ileal conduit urine, to minimize the pitfalls and increase diagnostic utility.     

可口革囊星虫肾管肌组织的结构特征

采用显微及亚显微技术观察了可1：7革囊星虫肾管肌组织的结构特征。肾管肌组织位于柱状上皮层下,由纵肌及环肌组成。肌细胞（肌纤维）呈长梭形,核位于细胞边缘并明显突向细胞外基质中,核周围有较多线粒体及少量内质网。肌纤维表面有许多囊状或指状突起的肌质囊,内含肌浆、光面内质网、线粒体及糖原颗粒。肌质囊之间的肌膜内面具膜相关电子致密斑。肌纤维内含粗、细两种肌丝,细肌丝围绕在粗肌丝周围,在肌丝之间分布有糖原颗粒、线粒体及胞质致密体。线粒体及糖原为肌纤维的代谢提供能量,肌组织的收缩对促进肾管的过滤排泄及繁殖时配子进入肾管可能起重要作用。     

Cytopathology of extramedullary plasmacytoma of the bladder: a case report

BACKGROUND: Plasmacytoma of the bladder is an extremely rare tumor, with all information concerning this neoplasm derived from case reports. It can be a major diagnostic pitfall on both histology and urine cytology. CASE: A 95-year-old woman presented with gross hematuria and a large bladder mass detected by ultrasound. The case was initially misdiagnosed as a high grade urothelial carcinoma. Since the urine cytology did not show the classical cytologic features of urothelial carcinoma, the histologic sections were reviewed and immunohistochemical staining performed. The final diagnosis was plasmacytoma of the bladder. Subsequently the patient underwent a skeletal survey and bone scan, which did not reveal any lesion suspicious for multiple myeloma. The patient was scheduled for radiotherapy. CONCLUSION: In this case of bladder plasmacytoma, urine cytology provided a clue to the diagnosis. Urine cytology can be a diagnostic tool to help make this diagnosis in the case of poorly differentiated bladder neoplasm, especially in a patient with a known history of multiple myeloma.     

Role of the nephridia in the elimination of foreign cells from the coelomic fluid of two polychaete annelids, with observations on the structure of the nephridia

Formalinized sheep red blood cells and living bacteria (Serratia marinorubra) are rapidly phagocytosed. When infected into Arenicola marina and Neoamphitrite figulus. Phagocytes clump but later disperse. After sheep red cells have been taken up by phagocytes they migrate through the nephridial cells into the lumen. After bacteria have been taken up by the phagocytes they also clump and again later disperse but they are not found within the nephridial cell walls probably because the bacteria are effectively eliminated by the phagocytes. Formalinized red cells are probably indigestible and such particles can only be eliminated by active migration of the phagocytes to the exterior, or are sequestered or, more rarely, encapsulated. Loss of either red cells or bacteria directly through the nephridia is no more than can be accounted for by normal urine flow.     

The larval nephridia of the brackish-water polychaete,Nereis diversicolor

The larval nephridia of the brackish-water polychaete Nereis diversicolor are described for the first time, and have been studied to determine if their times of development and structural characteristics are consistent with a role in the osmotic regulation of the larva. As shown in serial paraffin sections and by interference-contrast optics, the nephridia of the three-setiger larva consist of a single pair of very large metanephridia, arising in the 3rd larval setiger, but with their elongated terminal ducts and coiled ciliated tubules pushed forward into the 2nd setiger; their open metanephrostomes and anterior anchoring filaments lie dorsal to the 2nd set of setae. In contrast, the definitive or juvenile metanephridia, arising in the 4th and subsequently formed setigerous segments, have short terminal ducts and coiled ciliated tubules confined to the segments on which their external nephropores open; their nephrostomes are ventrally located and open into the rear of the next anterior segment. These findings are in contrast to the claims of Edouard Meyer (1887), who described two pairs of closed protonephridia in the 2nd and 3rd larval setigers of Perinereis cultrifera. Although it is not excluded that the single larval pair of metanephridia of N. diversicolor may arise as protonephridia, Meyer's claim of two pairs of larval protonephridia was an observational error. The larval nephridia of the marine Platynereis dumerilii resemble in form, but are considerably smaller than, those of N. diversicolor. It is concluded that the hypertrophied pair of larval metanephridia of N. diversicolor is an evolutionary adaptation to existence in habitats of low and unpredictably varying salinity. Their development occurs irrespective of the prevailing salinity; hence, it must be genetically determined.     

In situ perfusion study of sodium transport across the nephridia of a marine invertebrate Sabella pavonia S. (Polychaeta; Annelida)

• 1.1. A suitable perfusion rate (0.110μl/min) was calculated after measuring nephridial volume and urine transit time.
• 2.2. Neither inulin nor albumin were found suitable as water movement markers for nephridia.
• 3.3. There was no net sodium flux through the nephridial wall.
• 4.4. Measurements of net nsodium flux through the nephridia showed that, in normal sea water, Sabella could not transport large amounts of sodium against a concentration gradient. A unidirectional sodium flux of about 10nequiv/min per cm crossed the nephridia.

     

Plasmacytoma with involvement of the urinary bladder. Report of a case diagnosed by urine cytology

BACKGROUND: Plasmacytoma of the bladder is a rare but important entity. We report a case of plasmacytoma of the bladder that was diagnosed by urinary cytology. CASE: A 71-year-old male with a history of multiple myeloma presented in renal failure. Renal ultrasound revealed right-sided, moderate hydronephrosis with a 4 x 4-cm, posterolateral, obstructing mass. Magnetic resonance imaging demonstrated a bladder mass involving the bladder base, right lateral wall and dome with extension into the perivesical tissues on the right. The mass showed a moderate degree of enhancement following intravenous gadolinium administration. Urine cytology was performed to evaluate for bladder carcinoma or other malignancies besides plasmacytoma. The specimen was signed out as multiple myeloma of the bladder. Cystoscopy and biopsy were subsequently performed on the bladder mass. The diagnosis of plasmocytoma was made, confirming the urine cytology diagnosis. CONCLUSION: Urinary cytology can be a diagnostic tool for plasmocytoma involving the bladder.     

Hydration status affects urea transport across rat urothelia

Although mammalian urinary tract epithelium (urothelium) is generally considered impermeable to water and solutes, recent data suggest that urine constituents may be reabsorbed during urinary tract transit and storage. To study water and solute transport across the urothelium in an in vivo rat model, we instilled urine (obtained during various rat hydration conditions) into isolated in situ rat bladders and, after a 1-h dwell, retrieved the urine and measured the differences in urine volume and concentration and total quantity of urine urea nitrogen and creatinine between instilled and retrieved urine in rat groups differing by hydration status. Although urine volume did not change >1.9% in any group, concentration (and quantity) of urine urea nitrogen in retrieved urine fell significantly (indicating reabsorption of urea across bladder urothelia), by a mean of 18% (489 mg/dl, from an instilled 2,658 mg/dl) in rats receiving ad libitum water and by a mean of 39% (2,544 mg/dl, from an instilled 6,204 mg/dl) in water-deprived rats, but did not change (an increase of 15 mg/dl, P = not significant, from an instilled 300 mg/dl) in a water-loaded rat group. Two separate factors affected urea nitrogen reabsorption rates, a urinary factor related to hydration status, likely the concentration of urea nitrogen in the instilled urine, and a bladder factor(s), also dependent on the animal's state of hydration. Urine creatinine was also absorbed during the bladder dwell, and hydration group effects on the concentration and quantity of creatinine reabsorbed were qualitatively similar to the hydration group effect on urea transport. These findings support the notion(s) that urinary constituents may undergo transport across urinary tract epithelia, that such transport may be physiologically regulated, and that urine is modified during transit and storage through the urinary tract.     

miR-126 在膀胱癌患者尿液中的表达及临床意义

目的:探讨miR-126在膀胱癌患者尿液中的表达与临床病理特征的关系,评估miR-126的肿瘤标志物诊断价值。方法:收集48例初发膀胱尿路上皮癌患者与32例健康对照者晨尿,提取尿液总RNA,通过实时荧光定量PCR技术检测各样本中的miR-126的表达水平,并经受试者工作曲线(ROC)分析其诊断价值。结果:膀胱癌患者尿液中的miR-126表达水平相对健康对照组明显上调(P0.01),其表达水平在不同病理级别之间存在显著差异(P均0.05),且低级别组表达水平略高于高级别组,与肿瘤大小、数目以及淋巴转移也有一定的相关性(P0.05),而与患者的年龄、性别、TNM分期等均无相关性(P0.05)。通过ROC曲线分析尿液中miR-126诊断膀胱肿瘤的曲线下面积(AUC)为0.861,当最佳切点定在7.475时,miR-126诊断膀胱肿瘤的敏感性和特异性分别为75.0%、81.2%。结论:膀胱癌患者尿液中miR-126的表达差异能够反映病情进展程度,其表达水平对膀胱肿瘤的早期诊断及病情评估具有一定的价值。