Long-Term Responses to Loss of Renal Mass: Control Mechanisms: Glomerulotubular Dimensional Readjustments During Compensatory Renal Hypertrophy in the Hypothyroid Rat

Although growth of tubules is arrested and that of glomeruli retarded by hypothyroidism in rats, unilateral nephrectomy has been found to elicit a vigorous compensatory hypertrophy of the hypothyroid kidney. Microdissection and measurement of the dimensions of glomeruli and proximal convoluted tubules taken from the kidney removed first and from the hypertrophic contralateral organ removed two to three weeks later, disclosed a “normalization” of the typical glomerulotubular dimensional imbalance as a result of greater tubular than glomerular growth. A somewhat more striking but qualitatively identical response was observed in 9 euthyroid animals. Glomerular filtration rate and maximal glucose reabsorptive capacity (Tm_G) increased in both euthyroid and hypothyroid animals in accord with the structural shifts.     

Tandem scanning confocal microscopy (TSCM) of normal and ischemic living kidneys

Tandem Scanning Confocal Microscopy (TSCM) allows one to section optically into and record real-time images of living organs and tissues in a noninvasive fashion. In this paper, we will present some initial TSCM observations of subcapsular nephrons in the living, intact kidneys of Munich-Wistar rats and evaluate the nephron's responses to temporary ischemia and to intravenous infusion of mannitol. The rats were anesthetized with Inactin and a laparotomy performed to expose the kidneys. Using a TSCM equipped with a 20 x water-immersion objective, we optically sectioned through the intact kidney capsule and recorded real-time images of living subcapsular glomeruli and uriniferous tubules. The proximal tubule brush border was highly reflective and allowed us to distinguish between the first and second segments of the proximal tubules as well as the distal tubules. Cellular elements of the blood could be seen passing rapidly through peritubular capillaries and individual glomerular capillary loops. With fluorescent filters in place, intravenously injected carboxyfluorescein was seen to pass through the glomerular capillary loops and then progressively through the different segments of the uriniferous tubules. Ligation of the renal artery resulted in rapid swelling of proximal tubule cells into the tubular lumens, loss of reflectiveness of the microvillous brush borders, and closure of the peritubular capillary spaces. Upon release of the ligature, the proximal tubule lumens again became patent, often opening up abruptly and in a zipper-like fashion down the length of the tubules. Increasing the glomerular filtration rate by intravenous infusion of mannitol resulted in increases in tubular luminal and perimeter dimensions. Mannitol also acted as an effective impermeant osmotic agent and prevented most of the cellular swelling which was otherwise seen in response to renal ischemia.     

The aglomerular kidney of the deep-sea gulper eel <Emphasis Type="Italic">Saccopharynx ampullaceus</Emphasis> (Saccopharyngiformes: Saccopharyngidae)

We report the presence of an aglomerular kidney in the pelagic deep-sea fish Saccopharynx ampullaceus (Saccopharyngiformes: Saccopharyngidae). The thin kidney is unpaired and ribbon-like rostrally, while it is thicker caudally with a rod-like shape. Light microscopic observation of serial sections revealed no glomeruli at all. The kidney is composed of renal tubules, sinusoids and capillaries of the renal portal system and extensive interstitial lymphoid tissues. Each renal tubule is surrounded by well-developed renal portal sinusoids, and the tubules are well separated from each other. There is a large space dorsal to the vertebrae, similar to the situation in the closely related Eurypharynx pelecanoides. We consider that S. ampullaceus possesses an aglomerular kidney to gain neutral buoyancy. The urinary bladder of S. ampullaceus is a distinct vesicular structure, unlike that of E. pelecanoides.     

Effects of locally formed angiotensin II on renal hemodynamics

The kidney produces angiotensin II (AngII) by conversion of both locally formed and systemically delivered angiotensin I (AngI). The latter may be physiologically significant because the kidney can convert 20-25% of systemically delivered AngI. To determine possible differences between the effects of circulating and locally converted AngII, we compared the renal responses to renal arterial infusions of AngI and AngII in equiconstrictor doses. Both reduced the renal blood flow and increased the filtration fraction; it is important that the AngI infusions consistently reduced glomerular filtration rates (GFR), which indicates effects proximal to or at the glomerulus. Micropuncture experiments revealed that AngI infusions reduced proximal tubular and peritubular capillary pressures and the single-nephron GFR; glomerular capillary pressure was not altered significantly. AngI infusions increased both pre- and postglomerular resistances and reduced the glomerular filtration coefficient. In other studies designed to estimate net intrarenal AngII generation, it was determined that the kidney degrades about 90% of arterially delivered AngII. Thus, most of the AngII in renal venous blood was formed intrarenally. Local production of AngII was enhanced, in association with increased renin release, after reductions in renal arterial pressure. Such increases in intrarenal AngII production may contribute to the AngII-dependent changes in renal vascular resistance that occur in conditions where the renin-angiotensin system is stimulated.     

Altered renal morphology in transgenic mice with cholecystokinin overexpression

Although cholecystokinin is a regulatory peptide with a predominant role in the brain and the gastrointestinal tract, there is an increasing evidence for its role in the kidney. The aim of this study was to reveal morphological changes in the structure of kidney of mice with cholecystokinin overexpression by means of light, transmission and scanning electron microscope, and atomic force microscopy. Using immunohistochemistry the expression of important basement membrane proteins collagen IV, laminin and fibronectin, as well the distribution of cholecystokinin-8 in the renal structures was evaluated. The altered morphology of kidneys of mice with cholecystokinin overexpression was seen by all microscopic techniques used. The renal corpuscles were relatively small with narrow capsular lumen. The basement membranes of renal tubules were thickened and the epithelial cells were damaged, which was more pronounced for distal tubules. Characteristic feature was the increased number of vesicles seen throughout the epithelial cells of proximal and especially in distal tubules reflecting to the enhanced cellular degeneration. The relative expression of laminin but not collagen IV in the glomerular basement membrane was higher than in the tubular basement membranes. The content of fibronectin, in opposite, was higher in tubular membranes. Cholecystokinin-8 was clearly expressed in the glomeruli, in Bowman’s capsule, in proximal and distal tubules, and in collecting ducts. Ultrastructural studies showed irregularly thickened glomerular basement membranes to which elongated cytopodia of differently shaped podocytes were attached. As foot processes were often fused the number of filtration pores was decreased. In conclusion, cholecystokinin plays important role in renal structural formation and in functioning as different aspects of urine production in mice with cholecystokinin overexpression are affected-the uneven glomerular basement membrane thickening, structural changes in podocytes and in filtration slits affect glomerular filtration, while damaged tubular epithelial cells and changed composition of thickened tubular basement membranes affect reabsorption.     

Effect of vasoactive intestinal polypeptide on the cyclic adenosine monophosphate generating system in rat kidney glomeruli and cortical tubules

The effect of in vitro addition of vasoactive intestinal polypeptide (VIP) on the 3'-5'-cyclic adenosine monophosphate (cAMP) generating system in rat kidney glomeruli and cortical tubules was studied. VIP did not stimulate cAMP accumulation in glomeruli; but VIP did stimulate, specifically and in a dose-dependent manner, cAMP concentrations in tubular membranes with the addition of GTP. These results are consistent with the existence of a functionally active VIP receptor coupled to adenylate cyclase in rat kidney cortical tubules.     

Gross,histological and ultrastructural morphology of the aglomerular kidney in the lined seahorse Hippocampus erectus

Histologic evaluation of the renal system in the lined seahorse Hippocampus erectus reveals a cranial kidney with low to moderate cellularity, composed of a central dorsal aorta, endothelial lined capillary sinusoids, haematopoietic tissue, fine fibrovascular stroma, ganglia and no nephrons. In comparison, the caudal kidney is moderately to highly cellular with numerous highly convoluted epithelial lined tubules separated by interlacing haematopoietic tissue, no glomeruli, fine fibrovascular stroma, numerous capillary sinusoids, corpuscles of Stannius and clusters of endocrine cells adjacent to large calibre vessels. Ultrastructural evaluation of the renal tubules reveals minimal variability of the tubule epithelium throughout the length of the nephron and the majority of tubules are characterized by epithelial cells with few apical microvilli, elaborate basal membrane infolding, rare electron dense granules and abundant supporting collagenous matrix.     

Renal distribution of ganglioside GM3 in rat models of types 1 and 2 diabetes

Ganglioside GM3 is particularly abundant in the kidney tissue and is thought to play an important role in the maintenance of the charge-selective filtration barrier of glomeruli. Altered expression of ganglioside GM3 was pathologically related with glomerular hypertrophy occurring in diabetic human and rat kidneys. Considering the role of GM3 ganglioside in kidney function, the aim of this study was to determine the difference in expression of GM3 ganglioside in glomeruli and tubules using immunofluorescence microscopy both in rat models of types 1 and 2 diabetes mellitus. Diabetes was induced with streptozotocin (55 mg/kg for type 1 diabetes and 35 mg/kg for type 2 diabetes) injection to male Sprague–Dawley rats which were fed with normal pellet diet (type 1 diabetes) or high-fat diet (type 2 diabetes). Rats were sacrificed 2 weeks after diabetes induction, frozen renal sections were stained with primary antibody GM3(Neu5Ac) and visualized by secondary antibody coupled with Texas red. In addition, renal gangliosides GM3 were analyzed by high-performance thin-layer chromatography followed by GM3 immunostaining. Immunofluorescent microscopy detected 1.7-fold higher GM3 expression in tubules and 1.25-fold higher GM3 in glomeruli of type 1 diabetes mellitus compared with control group. Type 2 diabetes mellitus rats showed slight GM3 increase in whole kidney, unchanged GM3 in glomeruli, but significant higher GM3 expression in tubules, compared with control animals. Taking into consideration increased tubular GM3 content in both types of diabetes, we could hypothesize the role of GM3 in early pathogenesis of diabetic nephropathy.     

Regulation of glomerular filtration rate and sodium excretion by angiotensin II

In addition to its extrarenal functions, including the control of arterial pressure and aldosterone secretion, the renin-angiotensin system (RAS) also has multiple intrarenal actions in controlling glomerular filtration rate (GFR) and sodium excretion. Angiotensin II (AngII) helps to prevent excessive decreases in GFR in different physiological and pathophysiological conditions by preferentially constricting the efferent arterioles, an action that can be mediated by either intrarenally formed or circulating AngII. Circulating AngII and intrarenally formed AngII do not appear to directly constrict preglomerular vessels, including the afferent arterioles, when the RAS is activated physiologically. The sodium-retaining action of AngII may be due, in part, to constriction of efferent arterioles and to subsequent changes in peritubular capillary physical forces. However, AngII may also directly stimulate sodium reabsorption in proximal and distal tubules, although the exact site at which AngII increases distal tubular transport is still uncertain. Considerable evidence indicates that the direct intrarenal effects of AngII on tubular reabsorption, including those caused by changes in peritubular capillary physical forces or a direct action on tubular transport, are quantitatively more important than those mediated by changes in aldosterone secretion. Thus, the intrarenal effects of AngII provide a mechanism for stabilizing the GFR and excretion of metabolic waste products while causing sodium and water retention, thereby helping to regulate body fluid volumes and arterial pressure.     

Renal effects of atrial natriuretic factor in domestic fowl

The renal hemodynamic and tubular effects of ANF were investigated using the Sperber technique in chickens. This technique takes advantage of the unique portal circulation of the avian kidney and permits direct access to the renal peritubular space independent of renal arterial blood flow and glomerular filtration. Infusion of ANF into the avian renal portal system increased urine flow rate and sodium excretion by as much as 300% and 100%, respectively. These changes occurred in the absence of significant alterations in glomerular filtration rate or renal plasma flow. There was no significant difference in urine flow, sodium excretion or glomerular filtration rate between the ANF-infused kidney and the contralateral, non-infused kidney. We conclude that the diuretic and natriuretic effects of ANF do not depend on changes in glomerular filtration rate and that the site of action of ANF is the renal medulla.     

Renal architecture of the dogfish Scyliorhinus caniculus (Chondrichthyes,Elasmobranchii)

Summary The excretory portion of the opisthonephric kidney of Scyliorhinus caniculus displays a mesial zone that is supplied with venous blood by the renal portal system and with arterial blood from the efferent arterioles of the glomeruli, and a zone of lateral bundles that is irrigated with arterial blood via arterioles in parallel to the afferent arterioles of the glomeruli. Each single nephron performs two large convolutions in the mesial tissue and two hairpin loops in the bundle. The nephron is differentiated into renal corpuscle (located between the two zones), neck segment (in the bundle), proximal segment I (beginning in the bundle, major convolution between the zones), proximal segment II (exclusively in the mesial zone), intermediate segment (beginning in the mesial tissue and ending in the bundle), distal segment (exclusively in the bundle) and collecting tubule (beginning in the bundle, with a large convolution in the mesial tissue and ending in the bundle) that joins the collecting duct-ureter system. In the bundles proximal and distal nephron segments, the end of the renal tubule and a central bundle vessel are arranged together and form a complex countercurrent system that is enclosed in a sheath of connective tissue. The bundles provide the structural basis for the creation of an environment with low urea concentration around the final portion of the renal tubules, which is consistent with previous experimental evidence of a significantly lower urea content of the bundles as compared with the blood and the mesial tissue in another marine elasmobranch, Raja erinacea. This condition is thought to lead to passive reabsorption of urea from the fluid of the end of the renal tubule. Separation of individual nephrons in the bundle zone appears to be correlated with the peculiar secondary structure that results from the folding of the bundles and may be in addition a requirement in conjunction with intermittent function of the glomeruli. The zonation of the renal tissue with formation of bundles with counter-current systems is characteristically found in marine Elasmobranchs and is considered to be the morphological correlate to the physiological ability of the marine Elasmobranchii to use urea for osmoregulation.     

Effects of Copper Supplementation on the Structure and Content of Elements in Kidneys of <Emphasis Type="Italic">Mosaic</Emphasis> Mutant Mice

Menkes disease is an effect of ATP7A gene mutation in humans, coding the Cu-ATP-ase which is essential in intestinal copper absorption and its subsequent transfer to circulation. This mutation results in a deficiency of copper in all tissues except the epithelia of intestine and kidney tubules. Subcutaneous injection of copper ions is the main therapy for Menkes patients. Mosaic (Atp7a^mo-ms) mice closely simulate the situation in Menkes disease. The aim of this study was to evaluate the changes in structure and element content in kidneys of mosaic mice after copper supplementation. Hematoxylin–eosin staining was used to analyze tissue morphology and atomic absorption spectrometry to estimate Cu and Zn content. X-ray microanalysis was performed to measure Na, Mg, P, Cl, and K content in the cells of the proximal and distal tubules. Copper administration lengthened the lifespan of the mutants but led to its high accumulation and results in severe kidney damage. Karyomegalia, necrosis of tubular and Bowman’s capsule epithelium, lesions, and atrophy of glomeruli were observed in the treated mutants. Copper treatment afterwards led to sclerosis of glomeruli and tubules enhanced proliferation of epithelial cells and formation of both polycystic and papillary carcinoma patterns in kidney. We suggest that copper excess may impair the activity of Na⁺/K⁺ ATP-ase in renal tubules of ms/− males. The content of Mg, P, and Cl in kidneys in mutants was also changed after copper administration.     

Serum hippurate and its excretion in conservatively treated and dialysed patients with chronic renal failure.

54 healthy volunteers or patients with normal kidney and liver function, 17 patients with decreased kidney function and 12 dialysed patients were evaluated for their serum hippurate accumulation and kidney excretion. It was found that there was an inverse relationship between serum hippurate and the clearance of endogenous creatinine (CCr) and a free relationship between fractional excretion of hippurate and CCr. The excretory capacity in residual nephrons was increased. This was caused by the greater glomerular filtration load which increased up to 25 times and tubular secretion which increased 7 times in dialysed patients. The relative contribution of glomerular filtration to hippurate excretion rose from about 20% in controls to almost 50% in dialysed patients. True kidney adaptation was localized in the organic anion transport system of proximal tubules.     

Renal cortex guanylate cyclase. Preferential enrichment in glomerular membranes.

1. The localisation and some of the properties of rabbit kidney cortex guanylate cyclase (GTP pyrophosphatase lyase (cyclizing) EC 4.6.1.2) have been studied. Upon fractionation of dissociated renal cortex, guanylate cyclase activity was preferentially enriched in fractions of pure glomeruli, where its specific activity was 44.5 times that measured in tubular fragments. Most, if not all, of the glomerular activity was found to be firmly membrane-bound, whereas the guanylate cyclase activity of the tubules was mainly soluble. Therefore, particulate guanylate cyclase activity could serve as marker enzyme for kidney glomeruli. 2. All hormones or hormone-like agents tested were without effect on kidney guanylate cyclase activity. Triton X-100 stimulated both glomerular and tubular activity. 3. Considering the high cyclic GMP forming capacity of kidney glomeruli, part of the cyclic GMP found in urine might be synthetized locally in these structures.     

Renal and systemic effects of synthetic atrial natriuretic factor

A synthetic peptide corresponding to a sequence of 26 amino acids contained in endogenous rat atrial natriuretic factor (ANF), was infused into one renal artery of anesthetized dogs for a comprehensive in vivo evaluation of the renal and systemic effects of pure ANF. The results proved conclusively that ANF acted directly on the kidney since urine volume and fractional excretion of sodium, potassium, chloride and calcium were elevated in a dose-related manner in the ANF-treated kidney, but were not significantly affected in the contralateral saline-infused organ. The maximum effects achieved with the synthetic ANF were higher than any reported following intravenous administration of crude extracts of rat atria and were similar to those produced by thiazide diuretics. In four of the five dogs studied, renal vascular resistance fell progressively as doses of ANF were increased. Glomerular filtration rate was not significantly elevated during ANF infusion, but was correlated with sodium excretion rates. Even though mean arterial pressure was progressively reduced, there was no significant change in heart rate and no stimulation of renin secretion. Arterial cyclic GMP concentration was higher in the basal state and rose more rapidly than did renal venous levels, indicating that increases in circulating concentrations of arterial cyclic GMP originated from an extrarenal source. Dose-related elevations in urinary cyclic GMP excretion could be explained by increased cyclic GMP filtration, by enhanced production in tubular cells, or by renal tubular secretion. Especially in the saline-infused kidney, there was a clear dissociation between excretion of cyclic GMP and fractional sodium excretion. We conclude that the synthetic ANF increased electrolyte excretion via a direct renal action which was not solely dependent upon changes in renal vasculature, renin secretion or cyclic GMP levels.     

Light and Electron Microscopical Studies of the Renal Lesion in Dogs With Pyometra

Kidney biopsies from 23 bitches with pyometra and an entire kidney from four pyometra bitches were examined by light microscopy. Kidney tissue was also taken from three bitches at different intervals after ovariohysterectomy for pyometra. All the pyometra bitches had membranous glomerulonephritis or mixed proliferative and membranous glomerulonephritis. Two of the bitches had intraglomerular hyaline nodules resembling those seen in conjunction with diabetes in human beings. The degree of glomerular damage could be correlated with the reduction in glomerular filtration rate determined by function tests. The proximal tubules generally contained numerous hyaline droplets but the degree of this change could not be correlated to the degree of glomerular damage. A yellow pigment, a lipofuscin, was regularly present in the proximal tubules as well as epithelial proliferation and mitoses. Focal atrophy of tubules also occurred, presumably because of obliteration of glomeruli. The cortical interstitium contained collections of mature and immature plasma cells, often surrounding the glomeruli. When the kidneys from three bitches were examined after ovariohysterectomy for pyometra, the glomerular damage in two had regressed to leave only slight thickening of the capillary walls. In the third bitch, examined only 14 days after ovariohysterectomy, healing was partial. Kidney tissue from five bitches was also examined by electron microscopy. The glomerular endothelial cells were swollen and the basement membrane was grealy thickened. With more severe degrees of glomerular damage, an electron-dense material was deposited along the inner surface of the basement membrane and the swollen mesangial cells contained numerous inclusions. There was focal fusion of the foot processes of the glomerular epithelial cells; in one bitch with heavy proteinuria, the fusion was widespread. The proximal tubules contained numerous protein absorption droplets representing resorbed protein. The tubular basement membrane at all levels was thickened. Because of similarities with some other types of renal damage (nephrotoxic nephritis in dogs and acute proliferative glomerulonephritis in human beings), the possibility is broached that the renal lesion in pyometra is the result of an immunobiological process.     

Tridimensional ultrastructure of freeze-fractured rat kidney cortex (studied in stereo)

The tridimensional ultrastructure of the inner cortex of rat kidney has been studied by observing freeze-fractured tissue in stereo. The complex structure of the tubules, fenestrated capillaries and glomeruli is more readily observed through the irregular fracturing of the tissue that occurs in this technique. The ultrastructure of the brush border and interdigitating membranes of the proximal tubules, the structure of the fenestrated endothelial membranes of the capillaries and the ribbonlike appearance of the filtration space between the foot processes of the glomeruli were especially well depicted in stereo images of freeze-fractured renal tissue.     

Autoregulation of avian renal plasma flow: contribution of the renal portal system

Summary A simplified avian kidney model was used to assess renal plasma flow (RPF) at normal (100–110 mmHg) or unilaterally reduced (40–50 mmHg) renal arterial perfusion pressure (RAPP) in domestic fowl with ambient (AMBIENT group) or restricted (RESTRICTED group) renal portal flow. Direct measurement of para-aminohippuric acid (PAH) extraction efficiencies (E_PAH) allowed avian RPF to be calculated from the clearance of PAH (C_PAH). E_PAH was unaffected by RAPP, thereby validating the use of PAH to estimate RPF during experimental hemodynamic manipulations. C_PAH and RPF were unaffected by RAPP in the AMBIENT group (perfect autoregulation), but decreased significantly compared with contralateral kidney values during reduction of RAPP in the RESTRICTED group. Urine flow and glomerular filtration rates (GFR) were reduced unilaterally along with RAPP, regardless of the portal perfusion status. The renal portal system contributes to overall RPF autoregulation in domestic fowl, helping to maintain constancy of renal blood flow even after RAPP is reduced well below the GFR autoregulatory limit.Abbreviations BW body weight - C _In Clearance of inulin - C _PAH clearance of PAH - E _PAH PAH extraction efficiency - FF filtration fraction - GFR glomerular filtration rate - LiOH lithium hydroxide - MT mammalian-type nephron - PAH para-aminohippuric acid - [PAH] _A concentration of PAH in arterial plasma - [PAH] _a chromagen corrected PAH in arterial plasma - [PAH] _E endogenous PAH-like chromagen - [PAH] _UF concentration of ultrafilterable PAH - [PAH] _v concentration of PAH in renal venous plasma - [PAH] _v chromagen corrected PAH in renal venous plasma - RAPP renal arterial perfusion pressure - RPF renal plasma flow - RT reptilian-type nephron - UFR urine flow rate - UFR per gram urine flow rate per gram kidney weight - T _M S PAH tubular secretory maximum for PAH - SEM standard error of mean     

Lipoxygenase activity in rat kidney glomeruli, glomerular epithelial cells, and cortical tubules

We examined the possibility that renal glomerular and cortical tubular tissue has lipoxygenase activity in addition to the well established cyclo-oxygenase pathway of arachidonic acid metabolism. Homogenized rat kidney glomeruli, in the presence of meclofenamate (33 microM) and divalent cation ionophore A23187 (3 microM), metabolized octatritiated arachidonic acid to 12-hydroxyeicosatetraenoic acid and lesser amounts of 80 and/or 9-hydroxyeicosatetraenoic acid. These products were identified by thin layer chromatography, high performance liquid chromatography, and gas chromatography-mass spectroscopy. In order to rule out the synthesis of hydroxylated fatty acids by platelets and leukocytes entrapped in the glomeruli, we studied lipoxygenase products in glomerular epithelial cells after 9 days in cell culture. Homogenized glomerular epithelial cells converted octatritiated arachidonic acid to 12-hydroxyeicosatetraenoic acid solely. The lipoxygenase activity in cortical tubules was substantially less than in glomeruli and only 12-hydroxyeicosatetraenoic acid was synthesized. The production of hydroxyeicosatetraenoic acid by lipoxygenase inhibitors, nordihydroguaiaretic acid, 5,-homogenized glomeruli, glomerular epithelial cells, and cortical tubules was inhibited by three 8,11,14-eicosatetraynoic acid, and 1-phenyl-3-pyrazolidone. These data demonstrate that there is lipoxygenase activity in rat kidney glomeruli, glomerular epithelial cells and to a lesser extent cortical tubules, and may imply a role of the lipoxygenase products in the regulation of normal glomerular function and inflammatory disease of the kidney.     

Effect of taurine on the microvessel exchange function and adrenergic response of veins and arteries in the cat skeletal muscle

In cats anesthetized with Uretan and perfused with a constant blood volume, Taurine induced responses of neither arterial nor venous vessels of the skeletal muscle but increased the capillary filtration coefficient without any significant change of the capillary pressure in the skeletal muscle's microvessels. Taurine also increased both the constrictor and the dilatory responses of the arterial and venous vessels. The mechanism of the Taurine effects upon the smooth muscle elements of arteries and veins as well as upon proper mechanisms of capillary pressure control and capillary filtration coefficient, seems to be calcium-dependent.