Peptidases in the kidney and urine of rats after castration

Summary The localization of various peptidases in the renal section of the rat was investigated histochemically, and their activities were determined fluorometrically in renal homogenate. The membrane-bound peptidases aminopeptidase A (APA), aminopeptidase M (APM), -glutamyl-transferase (-GT), dipeptidylpeptidase IV (DAP IV), and the lysosomal dipeptidyl peptidases I (DAP I) and II (DAP II) were investigated in male and female (estrus) rats both before and 30 days after castration. In addition, protein excretion and APA, APM, DAP I and DAP IV activities were measured in the urine of these animals. Histochemically, the membrane-bound peptidases are demonstrable mainly in the brush borders of the proximal tubules. In addition, APA and DAP IV are found in the glomeruli, -GT and DAP IV in the thin descending limbs of the loops of Henle, and -GT in the basal labyrinth of the S₂ and S₃ segments. The lysosomal peptidases are most concentrated in the S₁ and S₂ segments of the proximal tubule, in the distal tubule, and in certain cells of the connecting tubule and collecting duct, where they are contained in lysosomes of varying size. Sex differences and castration effects are demonstrable both histochemically and biochemically for the investigated peptidases. Histochemically these effects are most pronounced in the S₃ segments for the membrane-bound peptidases, and in the lysosomes of the proximal tubule for the lysosomal peptidases. Biochemical tests in controls show significantly higher lysosomal peptidase activities in the renal homogenate of females than of males. After castration the lysosomal peptidase activities in males increase, approaching those of females. This appears to have bearing on the sex-dependent proteinuria in rats, for lysosomal peptidases and proteinases are particularly important in the degradation of filtered proteins that are reabsorbed in the proximal tubule. In females high lysosomal peptidase activities correlate with a low proteinuria, while males demonstrate lower lysosomal peptidase activities and a significantly higher proteinuria than females. After castration, the lysosomal peptidase activities and proteinuria in males approach those in females. Renal peptidases are also excreted in the urine, again with sex differences, and so these excreted peptidases contribute to the proteinuria in rats.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)     

Electron microscopic and morphometric studies of the main kidney segment of male and female rats following castration and testosterone substitution

The effect of testosterone on the 3 segments of the renal proximal tubule (S1, S2, S3) of male and female rats was studied by electronmicroscopic and morphometric methods. Only light, granulated and dark lysosomes as well as microbodies (peroxisomes) and dictyosomes (Golgi zones) were investigated. After castration the area density of light lysosomes in the S1 segment increases in males whereas it decreases in females; therefore the sex different pattern of light lysosomes, that is to be seen in normal animals, is reversed. The absolute size and number of light giant lysosomes is also elevated in castrated males in comparison to normal animals as well as to animals substituted by testosterone. - Dark lysosomes of the S1 segments are more numerous in castrated females and less numerous in castrated males than in normal animals. - The distinct sex difference in dark lysosomes of the S2 segment which is demonstrable in normal animals disappears after castration the area density of dark lysosomes increasing in castrated females and decreasing in castrated males. The three species of lysosomes in the S1 segments show no longer a sex difference after substitution with testosterone: substituted males develop the same pattern as normal animals and substituted females are almost comparable with normal males. However, the sex difference in dark lysosomes of the S2 segment is more pronounced after testosterone treatment. - The characteristic pattern of light lysosomes in the S1 and S2 segments as well as the change of the sex different lysosomal pattern after castration and substitution with testosterone, respectively - especially in S1 - seem to be caused by testosterone which results in an inhibition of resorption. Only after castration a sex difference appears in dark lysosomes of the S3 segment (males show more dark lysosomes than females). This sex difference is reversed by testosterone treatment. There are more numerous lysosomes with an non-homogeneous matrix in both sexes after castration which are seldom to be seen in normal and substituted animals. The area density of microbodies shows sex differences in all 3 segments of normal animals. While no significant changes in S1 and S2 are to be seen after castration and substitution, there is a pronounced decrease of the area density of microbodies in S3 of males after castration, so that no sex differences are then available.(ABSTRACT TRUNCATED AT 400 WORDS)     

Histochemical,autoradiographic and electron microscopic investigations of the renal proximal tubule of male and female rats after castration

Summary After castration of 90-day-old male and female rats, changes appear in the renal proximal tubule. A distinction can be made between early changes (up to 10th postoperative day) and later changes (20th–30th postoperative day). Between the 3rd and 5th day after castration the kidney of the females shows an increase in free estrogen receptors (biochemical studies) which are localized in the pars contorta of the proximal tubule (autoradiographic studies), while the male kidney shows a marked increase in urinary protein excretion up to the 10th day after castration. Proximal tubule changes detectable histochemically and electron microscopically do not appear until day 20 or 30 after castration. The results of castration are similar in segments S₁ and S₂. By days 20 and 30 after castration there is a decrease in the activity of lysosomal enzymes (acid phosphatase, acid -galactosidase). Electron microscopy shows a conspicuous decrease in the number of giant lysosomes (mainly in females) and apical vacuoles (mainly in males). A marked increase in the number of lysosomes is found in the S₃ segment; females always have more lysosomes than males. The number of peroxisomes is also greatly increased; they appear circular in the females but can assume bizarre shapes in the males. Lipid droplets appear in the basal region of the tubule cell of segments S₂ and S₃ in the males. The sex differences are preserved in all segments even after castration and become even more pronounced in the S₃ segment.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)Dedicated to Prof. Dr. W. Graumann, Department of Anatomy, University of Tübingen, on the occasion of his 65th birthday     

The effect of sex hormones on the proximal tubules in the rat kidney

Summary The three segments (S₁, S₂, S₃) of the proximal tubule of the rat kidney were investigated, with special reference to lysosomes, after castration, estradiol application, and at the end of pregnancy. Especially in S₁ and S₂ castration induces an increase of cellular autophagy. The nuclei become smaller; endoplasmic reticulum (ER), ribosomes, and Golgi apparatus are reduced; catabolism predominates. In S₁ more giant lysosomes occur; the total number of lysosomes increases whereas acid phosphatase activity decreases at the same time. Sex differences which exist in untreated animals disappear. Substitution with estradiol causes an activation of the proximal tubule cells: Heterophagy predominates, and cellular autophagy is reduced. Nuclear size is unchanged; ER, ribosomes and Golgi apparatus show a clear increase. Giant lysosomes are absent in S₁. On the whole lysosomes are larger, but less numerous than after castration. Acid phosphatase is highly active. All changes are most evident in S₃. At the end of pregnancy the proximal tubule cells are stressed considerably: Pinocytotic activity increases, and large numbers of cell organelles and many lipid vacuoles can be observed. The basal lamina in S₁ and S₂ becomes thicker. Lysosomes enlarge and increase in number in all segments; giant lysosomes are absent in S₁; acid phosphatase activity is extremely high. The results indicate that sex hormones directly influence the regulation of the proximal tubule cell; moreover, they are indirectly important for the functioning of the kidney via changes in the whole organism.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)Dedicated to Prof. Dr. O. Bucher, Head of the Institute of Histology and Embryology of the University of Lausanne/Switzerland, on the occasion of his 65th birthday     

Quantitative histochemistry of the lysosomal dipeptidyl aminopeptidase II in the proximal tubule of the rat kidney

Summary The activity of the lysosomal dipeptidyl aminopeptidase II (DAP II) was measured by quantitative histochemical methods in the S₁/S₂ segments of the proximal tubule using freeze dried and celloidin mounted cryostat sections (FDC sections) of rat kidney. The methodological studies show that there is a linear relationship between the amount of reaction product and reaction time for the first 5 min, as well as section thickness between 4 and 10 m. Maximal DAP II activities were demonstrated at pH 5.5. The K _m of DAP II was about 2.3 mM. — In addition to the methodological studies, DAP II activity was also measured in the proximal tubule (S₁/S₂ segments) of experimental animals (sham-operated and castrated male and female rats). Sham-operated females showed significantly higher DAP II activities than males. DAP II activity increased significantly in castrated males so that there were no significant differences between castrated males, sham-operated and castrated females. The quantitative histochemical results are largely in agreement with biochemical data published earlier.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)Dedicated to Prof. Dr. T.H. Schiebler, Chairman of the Institute of Anatomy of the University of Würzburg, on the occasion of his 60th birthday     

Sex different cytochrome-c uptake in the proximal tubule of the rat kidney

The present study deals with the dose- and time-dependent uptake of cytochrome c (CYT c) in the proximal tubule of the rat kidney, and shows that there are segment and sex differences in the reabsorption of CYT c. Rats of both sexes were intravenously injected with different doses of CYT c (0.75-9.0 mg per 100 g body weight), and the kidneys were investigated by light and electron microscopy at different times (3 min, 10 min, and 2 h) after the injection. After 3 and 10 min, CYT c was demonstrated in apical vacuoles of different sizes and in some lysosomes of the S1 and S2 segments, whereas after 2 h, CYT c was found only in lysosomes of all three segments of the proximal tubule. At these times, the S1 segment contained more CYT c than the S2 and S3 segments. However, 2 h after the injection of 6 or 9 mg CYT c, the differences between the S1 and S2 segments disappeared almost completely, due to a strong lysosomal accumulation of CYT c in the S2 segment. At all studied times and CYT-c doses, the S3 segment contained less CYT c than the S1 and S2 segments. On the whole, different levels of CYT-c reabsorption were found in the different segments of the proximal tubule, which was saturable with increasing CYT-c doses, i.e. firstly in the proximal and then in the distal parts of the proximal tubule. Two hours after the injection of CYT c, a difference between males and females was observed, with the lysosomes of the S1 and S2 segments of females containing more CYT c than those of males. Thus, more CYT c was reabsorbed in the proximal tubule of females than in that of males.     

The fine structure of the nephronic tubule of the mudskipper Periophthalmus koelreuteri (Pallas)

Ultrastructural examination of the head kidney of Periophthalmus koelreuteri (Pallas) (Teleostei, Gobiidae) revealed that the nephronic tubule cells are bound by tight junctions and desmosomes with little intercellular space. The first proximal segment (PI) consists of low columnar cells with well developed brush borders, indented nuclei, and numerous apical endocytic vesicles and lysosomes. A second cell type possessing clusters of apical cilia and lacking brush border and lysosomes is occasionally found between PI cells. The second proximal segment (PII) is formed of high columnar cells with brush border, regular spherical nuclei and numerous mitochondria located between well developed infoldings of the basal membrane. Single ciliary structures protrude into the lumen from PI and PII cells. The distal segment is lined by low columnar epithelium with few microvilli, regular spherical nuclei, numerous scattered mitochondria, and microbodies. The collecting tubule cells are cuboidal with few euchromatic nuclei, some mitochondria, and secondary lysosomes.     

DISTRIBUTION OF PEROXISOMES (MICROBODIES) IN THE NEPHRON OF THE RAT : A Cytochemical Study

The distribution of peroxisomes (microbodies) in the rat nephron was studied cytochemically, using glutaraldehyde- or formaldehyde-fixed tissue, by means of α-hydroxy acid oxidase activity in light microscopy or oxidation of 3,3'-diaminobenzidine (DAB) at pH 9 in both light and electron microscopy.The two cytochemical methods show peroxisomes to be nearly sperical particles found only in cells of the proximal convoluted tubule. Lysosomes were identified in the same or parallel sections, with β-glycerophosphate or 5'-cytidylic acid as substrate. They are found in all cells of the nephron. These cytochemical methods visualize the two organelles for light microscopy; they also permit unequivocal differentiation of all kidney peroxisomes from lysosomes in electron micrographs. Peroxisomes are larger and more reactive in the cells of the pars descendens (P₃ segment) of the proximal convolution, located in the outer medulla and medullary rays, than in the cells of the pars convoluta (P₁ and P₂ segments), situated in the cortex. In contrast, lysosomes are much smaller in the P₃ segment and larger and more reactive in the P₁ and P₂ segments. In all cells of the proximal convolution, peroxisomes tend to be concentrated nearer the base of the cells than do lysosomes. Mitochondria in P₃ cells also show low levels of DAB oxidation at pH 6, in contrast to those in P₁ and P₂ cells. The possibility is discussed that P₃ cells possess an extramitochondrial means of oxidation in which peroxisome oxidases play an important role.     

Sex determination of the onion fly,Hylemya antiqua (Meigen)

X and Y chromosomes of Hylemya antiqua occur in two forms each. X_L and X_S, and Y₁ and Y₂. The larger X_L has an intercalary proximal segment which is absent in the more common smaller X_S. The acrocentric Y chromosome (Y₁), does not differ morphologically from X_S. A smaller metacentric Y₂ is apparently not homologous with Y₁. Two types of males, XY₁ and XXY₂, coexist in at least one Dutch population. XY₂ has been observed in one individual only. In larval ganglion cells an association has been observed between chromosome Y₂ and a probably non-homologous, intercalary segment of autosome 4. A numerical somatic variation of Y₂ can lead to gynandromorphs and sex ratios significantly different from 1∶1. XX cells can differentiate into functional spermatozoa in XX/XXY₂ mosaic testes. This indicates the presence of a diffusable male determining substance, which can reverse the “genotypic” sex of a cell. The occurrence of some spermatozoa-containing “cysts” in ovaries of two gynanders suggests a more or less autonomous (independent of the gonadal environment) differentiation of XXY₂ germ cells. XXXY₂ males and XXX females do not show a serious reduction in fertility. Even XXXXY₂ males do not exhibit any sign of intersexuality and spermatogenesis seems unaffected. All 62 scored M II cells of X-tetrasomic males contained 2 Xs.     

The mature mesonephric nephron of the rabbit embryo

Summary Transmission electron micrographs of the mesonephric nephron in 18 day rabbit embryos reveal major cytological structures reappearing in the nephron of the definitive rabbit kidney. The initial segment of the proximal tubule resembles (despite quite different cell proportions) the cell picture of the metanephric S₂-segment. The changes occurring at the end of the terminal proximal segment, the decrease in cell size, flattening of the nuclei, shortening of the brush border and reduction of Golgi profiles and endocytotic organelles largely parallel those between S₂ and S₃. The type of increased basolateral cell face of the proximal and distal tubule cells shows only quantitative differences to their metanephric counterparts. The distal tubule, which cannot be further subdivided (except the macula densa-region) exhibits varying degrees of cell interdigitations with vertically arranged and partially arching lateral ridges. This tubule matches closely the metanephric medullary straight part of the distal tubule, so that the sequence of the first mesonephric nephron segments is similar to the metanephric ones with the exception that the thin limb of Henle is absent. The large macula densa-region is characterized by its cell height and distended infranuclear spaces. The principal cells of the collecting tubule, with a few basal infoldings and intense short lateral interlockings resemble metanephric cells of the outer medullary collecting duct. The mitochondria-rich intercalated cells occur in dark and light contrasting forms and are more frequent than was evident from our SEM-study. The homogeneous cell population of the Wolffian duct is characterized by large glycogen deposits and comparatively smooth cell faces.     

The postnatal development of the rat kidney,with special reference to the chemodifferentiation of the proximal tubule

Summary New nephron anlages appear in the renal cortex up to the 4th postnatal day (PD). The last anlages to be formed develop into functional nephrons by PD 10, and the cortex appears mature at PD 12 after formation of the cortex corticis. The renal medulla develops by the longitudinal growth of loops of Henle and collecting ducts. The immature medulla cannot be divided into different zones and corresponds structurally to the later inner stripe of the outer zone. The inner zone is formed by PD 8, and the outer stripe of the outer zone by PD 12. The renal medulla is mature at PD 21.From the start of its development, the renal proximal tubule consists of the pars convoluta and pars recta. In both parts the formation of the brush border is accompanied by the simultaneous appearance of brush border enzymes (alkaline phosphatase, -glutamyltranspeptidase, dipeptidylamino-peptidase IV) and lysosomal enzymes (acid phosphatase, acid -galactosidase, N-acetylglucosaminidase, dipeptidylaminopeptidase II) over the full length of the proximal tubule. During the course of proximal tubule maturation, however, the lysosomal enzyme activities decline in the pars convoluta (with constant brush border enzyme activities), while the brush border enzyme activities increase in the pars recta (with constant lysosomal enzyme activities). The two parts further differ in that they exhibit different lysosomal patterns from the outset, the pars convoluta containing numerous large, highly enzyme-active lysosomes arranged in groups, and the pars recta containing only a few very small lysosomes with low enzyme activity. Thus, even in the newborn rat, the lysosomal pattern of the pars recta already corresponds to that of the mature S₃ segment. The S₁ and S₂ segments of the pars convoluta first differentiate between PD 10 and 21, as the groups of large lysosomes are progressively broken up and the extent of the lysosomal apparatus is diminished, this proceeding in a retrograde direction from the end of the immature pars convoluta.Supported by the Deutsche Forschungsgemeinschaft (SFB 105)     

Changes in lysosome populations in the rat kidney cortex induced by experimental proteinuria

1. Experimental proteinuria (262.9 mg protein/24 hr urine) was induced in rats by repeated intraperitoneal injections of BSA. 2. Hypertrophy of the kidney cortex was significant 8 days after the start of the BSA injections, and the activities of lysosomal enzymes in kidney cortex and urine were significantly higher in proteinuric compared to nonproteinuric rats. 3. Lysosome populations in the kidney cortex were examined by rate sedimentation of the homogenate and by rate zonal and isopycnic centrifugation of the lysosome-rich ML fraction. 4. The activity of lysosomal enzymes in the kidney cortex increased slightly, essentially in the large, fragile lysosomes mainly recovered from the proximal tubule. 5. Proteinuria induced a shift/reduction in the density of small lysosomes from 1.235 and 1.20 g/ml to 1.225 and 1.185 g/ml, respectively. 6. Proteinuria induced a new population of small lysosomes (density 1.185 g/ml) enriched in cathepsin D.     

Peptidases in the kidney of male rats following castration and testosterone substitution

The localization of aminopeptidase M (APM), dipeptidyl peptidase I (DAP I), II (DAP II) and IV (DAP IV) in the renal section was investigated histochemically, and their activities were determined fluorometrically in renal homogenate of normal, castrated and testosteron treated male rats.--After castration the activities of the lysosomal DAP II (pars convoluta of the proximal tubule), DAP I (distal and proximal tubule) and of the mainly membrane-bound DAP IV (glomeruli, brush border of the proximal tubule) increase in comparison to normal males, whereas the activities of the brush border-bound APM decrease. After testosteron treatment of castrated animals (0.1, 0.5 and 1.0 mg testosterone proprionate/100 g BW and day; 5-day treatment) the activities of DAP I, II and IV decrease again, so that after treatment with 0.1 mg testosterone proprionate, the activities of DAP I and II approach those in normal males.--The additionally determined urinary protein excretion shows that there is a significant decrease in proteinuria after castration, whereas testosterone treatment of castrated animals is accompanied by an increase of proteinuria.--Our results would suggest that the protein catabolism in the proximal tubule and the proteinuria are interrelated, and that testosterone influences (decreases) the protein catabolism in the proximal tubule. This means that high activities of lysosomal proteinases in the proximal tubule (castrates) are accompanied by a low proteinuria, and low activities of those proteinases (testosterone treated castrated or normal males) by a high proteinuria.     

Incorporation of 3H-thymidine in the nephron of Gasterosteus aculeatus L. and its stimulation by methyltestosterone

Summary The rate of ³H-thymidine incorporation into different parts of the renal proximal tubule of female sticklebacks treated with methyltestosterone was investigated using high-speed scintillation autoradiography. The results are compared with those from normal males before or after mucous transformation of the kidney. Labelled cells are observed in all parts of the proximal tubule, with marked variations from one segment to another. They are numerous in part 2 of the proximal tubule, particularly in the distal region. Male sex hormones affect the labelling rate in all parts of the nephron, especially in the distal region of part 2 of the proximal tubule. In that particular area, new tubule formation by budding is observed in some individuals, but this process does not appear to be a general one. Correlation between the frequency of these figures and the time of treatment could not be established. Comparing the action of sex hormones in females with that in males reveals a difference in reactivity in the proximal zone of part 2 of the proximal tubule, where methyltestosterone has a strong action in females; in contrast, in mature and immature males, only a few labelled cells are present in this region.It is concluded that kidney enlargement during the breeding season does not result only from a swelling of cells belonging to part 2 of the proximal tubule, as was generally believed, but also from a lengthening or even a proliferation of the proximal tubules, induced by an increase in mitotic activity controlled by male sex hormones.

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Résumé L'incorporation de thymidine tritiée dans les tubules proximaux du rein est étudiée par autoradiographie rapide chez des Epinoches femelles préalablement traitées par la méthyltestostérone. Les résultats sont comparés avec ceux obtenus chez des mâles normaux ayant ou non développé un rein muqueux. Des cellules marquées sont présentes à tous les niveaux des tubules proximaux, mais leur nombre varie considérablement d'un segment à l'autre. Elles sont les plus nombreuses dans la seconde partie du tubule proximal, particulièrement dans sa région distale. Le taux de marquage est modifié dans toutes les régions du néphron, mais les variations sont les plus intenses dans la région distale de la seconde partie du tubule proximal, où l'on observe parfois la formation de nouveaux tubules par bourgeonnement. La comparaison des résultats obtenus dans les deux sexes fait apparaître une différence de réactivité au niveau de la zone proximale de la seconde partie du tubule proximal, où la méthyltestostérone agit fortement chez les femelles, alors qu'elle n'exerce pas d'effet notable chez les mâles.L'augmentation de volume du rein chez le mâle lors de la période de reproduction ne résulte donc pas uniquement d'un gonflement des cellules de la seconde partie du tubule proximal, comme on le pensait généralement. Des phénomènes mitotiques interviennent également dans ce processus, sous l'influence des hormones sexuelles mâles, qui conduisent à un allongement, voire à une multiplication des tubules proximaux.

     

Maleate effects on kidney peptidases and proteinuria of male and female rats. Histochemical and biochemical studies

The effects of maleate on membrane-bound and lysosomal peptidases were studied histochemically in the kidney and biochemically in the kidney and the urine of male and female rats 6 h after the administration of two different doses of sodium maleate (150 and 300 mg/kg body weight). Additionally, the proteinuria of experimental animals was electrophoretically analysed to detect maleate-induced alterations in the urinary protein composition. The histochemistry of the brush-border peptidases (aminopeptidase A, gamma-glutamyltransferase) showed dose-dependent maleate effects in the late pars convoluta and the pars recta of the proximal tubule (blurring of the brush-border enzyme reaction pattern). The female animals were more severely affected by both maleate doses. After maleate treatment, enzyme-activity measurements in the kidney homogenate supernatant and urine indicated dose-dependent structural destruction of the proximal tubule, especially of brush-border membranes, and revealed an increase in enzyme excretion. Both the maleate-induced enzyme excretion and proteinuria were more pronouncedly increased in females than in males. Electrophoretic analysis of urinary proteins revealed alterations in the urinary-protein composition after maleate treatment, which favoured the excretion of proteins with a molecular weight higher than 20,000 daltons. Again, sex-related differences in the maleate effects were demonstrated. The results indicate that maleate causes alterations in the brush-border membranes and, especially at higher doses, results in cellular destruction selectively in the late proximal tubule of rat kidneys. Selectivity was also encountered in the maleate effects on urinary-protein composition, suggesting that the tubular alterations lead to an inhibition of the reabsorption of mainly high-molecular-weight proteins. Although the nature of the effects was independent of sex, it appears that females are less well protected against tubular damage caused by maleate.     

Role of ultrastructural techniques in understanding mechanisms of metal-induced nephrotoxicity

The combined use of ultrastructural morphometry and X-ray microanalysis in conjunction with biochemical analysis is one approach to elucidating mechanisms of metal nephrotoxicity at the cellular level. Ultrastructural morphometry conducted on proximal tubule cells of rats exposed to low levels of methyl mercury for prolonged periods of time showed statistically significant increases in the volume densities of the lysosomal and mitochondrial compartments. These findings were associated with marked changes in lysosomal marker enzymes and mitochondrial heme biosynthesis enzymes leading to the detection of a renal porphyrinuria that occurred before changes in standard tests of renal function. Ultrastructural morphometry, X-ray microanalysis, and biochemical studies of the low-molecular-weight tubular proteinuria produced by injection of cadmium metallothionein (CdMT) showed a rapid proximal tubule cell lysosome uptake and degradation of the CdMT complex, which led to a subsequent decrease in the numerical density (Nv) and average diameter of lysosomes and to an increase in the Nv of apical pinocytolic vesicles with time. The data indicate disruption of the normal primary lysosome-pinocytolic vesicle fusion process and related development of tubular proteinuria. Ultrastructural techniques may provide information useful in elucidating mechanisms of ongoing metal-induced nephrotoxic processes when consideration is given to sampling strategies for morphometric analysis and the inherent detection limits, elemental volatility, translocation effects, and limitations of quantification for X-ray microanalysis in soft biological tissues.     

Microbodies (peroxisomes) in the toad,Bufo marinus

Summary Microbodies (peroxisomes), a group of cytoplasmic organelles enriched in catalase, are demonstrated in the toad, Bufo marinus, by light and electron microscopy by means of a cytochemical staining procedure that demonstrates the peroxidatic activity of catalase with diaminobenzidine (DAB). Amphibian microbodies are similar to those of other classes in their fine structure and localization in hepatocytes and kidney, where they are prominent in the proximal tubular cells. Nucleoids are present only in renal microbodies. In the proximal renal tubule an unusual group of large brown granules are identified as lysosomes by their acid phosphatase, -glucosaminidase and -glucuronidase activities.This work was supported by U.S. Public Health Service Grants Nos. NS-06856 and HD 00674. We wish to thank Dr. Richard M. Hays who generously supplied us with toads; Dr. Alex B. Novikoff for making available facilities for ultramicrotomy, Miss Betty De Prest for technical assistance; Miss Marianne Van Hooren for preparation of the photomicrographs.     

The cytochemical demonstration of catalase and D-amino acid oxidase in the microbodies of teleost kidney cells

Synopsis The distribution of catalase and D-amino acid oxidase, marker enzymes for peroxisomes, was determined cytochemically in the kidney tubules of an euryhaline teleost, the three-spined stickleback.Catalase activity was localized with the diaminobenzidine technique. The presence of D-amino acid oxidase was determined using H₂O₂ generated by the enzyme, D-alanine as a substrate, and cerous ions for the formation of an electron-dense precipitate. Both enzymes appeared to be located in microbodies. The combined presence of these enzymes characterizes the microbodies as peroxisomes. Biochemically and cytochemically, no urate oxidase or glycolate-oxidizing L--hydroxy acid oxidase could be demonstrated.Stereological analysis of the epithelia lining the renal tubules showed that the fractional volume of the microbodies is 5 to 10 times higher in the cells of the second proximal tubules than in the other nephronic segments or the ureter. The fractional volume of the microbodies was similar in kidneys of freshwater and seawater fishes.     

The ultrastructural localisation of cadmium

Summary A modified technique for the ultrastructural localisation of heavy metals is described in this paper. The method involves precipitation of heavy metals as sulphides in the tissue by using (NH₄)₂S after brief fixation in glutaraldehyde. The sulphides are, in the presence of a physical developer, then used to catalyse the reduction of silver ions into visible molecular silver. This latter step of physical development has been normally carried out after embedding and sectioning. However, when we followed this method we found that the dark metal sulphide was lost from the tissue during the embedding in epoxy resin. Hence the method was unsuitable for our porposed experiment on the ultrastructural localisation of cadmium. We subsequently modified the technique primarily by treating very thin tissue slices with the developer before dehydration and embedding, thus eliminating any problem from sulphide loss. This modified technique was used to investigate the ultrastructural localisation of cadmium in the kidneys of mice which had been exposed to 50 ppm cadmium in their drinking water for up to eight months. The molecular silver was found to be located mainly in the proximal tubule cells, either as dense clumps in apical vesicles and lysosomes or diffuse grains throughout the cytoplasm of the cells particularly in the basal region. We interpret these results as indicating that cadmium is found in the apical vesicles, lysosomes and cytoplasm of proximal tubule cells.