Smaller sized particles are preferentially taken up by alveolar type II pneumocytes

Specific urea transporters are responsible for the rapid urea movements occurring in precise medullary structures of the mammalian kidney. Three of them, ensuring facilitated passive transports, have been cloned yet: UT2-long is responsible for the high vasopressin-dependent urea permeability of the terminal inner medullary collecting ducts; UT2-short is located along a short portion of the thin descending limbs of Henle's loops; UT11 is expressed along the descending vasa recta. These three transporters are involved in the accumulation of urea in the medulla, participating to the corticopapillary osmotic gradient required for urine concentration in the presence of antidiuretic hormone. UT2-long enables diffusion of urea in the inner medulla, and UT2-short and UT11 enable the recycling of this urea by counter-exchange. These transporters could also be involved in nitrogen balance by modulation of their expression according to the need for urea excretion (protein-rich diet), or for nitrogen conservation (protein-poor diet). Several other urea transporters, including active transporters responsible for urea secretion or reabsorption, remain to be cloned and characterized.     

Renal medullary circulation: morphological characteristics of vessels and their organization

The blood vessels of the renal medulla have several particular features. The supplying vessels of the renal medulla are the efferent arterioles of the juxtamedullary glomeruli. Thus, the blood supply is entirely postglomerular. The distribution of the blood within the renal medulla is effected by the descending vasa recta. Descending and ascending vasa recta form the vascular bundles. Descending vasa recta leave the bundles at any level of the medulla to feed the adjacent capillaries; the longest descending vasa recta reach the papillary tip. The capillary plexus are differently developed. A dense capillary plexus is present only in the inner stripe of the outer medulla. In the inner medulla the capillary plexuses are poorly developed. At these sites ascending recta contribute to the capillarisation. The ascending vasa recta originate from capillaries at any level of the medulla and ascend without joining together towards the intrarenal veins at the cortico-medullary border. They are capillary vessels with wide lumina. Within the outer stripe of the outer medulla these vessels are very narrowly associated with the tubules; interstitial spaces are very poorly developed at this site. These relationships are interpreted as a possible weak point of the medullary circulation in pathological situations.     

Genetic and behavioral determinants of waist-hip ratio and waist circumference in women twins

1. The microcirculation of the kidney is arranged in a manner that facilitates separation of blood flow to the cortex, outer medulla and inner medulla. 2. Resistance vessels in the renal vascular circuit include arcuate and interlobular arteries, glomerular afferent and efferent arterioles and descending vasa recta. 3. Vasoactive hormones that regulate smooth muscle cells of the renal circulation can originate outside the kidney (e.g. vasopressin), can be generated from nearby regions within the kidney (e.g. kinins, endothelins, adenosine) or they can be synthesized by adjacent endothelial cells (e.g. nitric oxide, prostacyclin, endothelins). 4. Vasoactive hormones released into the renal inner medullary microcirculation may be trapped by countercurrent exchange to act upon descending vasa recta within outer medullary vascular bundles. 5. Countercurrent blood flow within the renal medulla creates a hypoxic environment. Relative control of inner versus outer medullary blood flow may play a role to abrogate the hypoxia that arises from O2 consumption by the thick ascending limb of Henle. 6. Cortical blood flow is autoregulated. In contrast, the extent of autoregulation of medullary blood flow appears to be influenced by the volume status of the animal. Lack of medullary autoregulation during volume expansion may be part of fundamental processes that regulate salt and water excretion.     

A flavinogenic mutant of the yeast Pichia guilliermondii with impaired iron transport

We recently demonstrated that net fluid uptake occurs in the capillary system of the inner medulla. To define the site of fluid uptake, the concentration of protein was determined in plasma from descending vasa recta at the base and tip of the exposed papilla in Munich-Wister rats. The vasa recta plasma-to-arterial plasma protein concentration ratio (VR/P) was 1.43 +/- 0.09 at the base and 1.66 +/- 0.09 at the tip. These results, which indicate fluid loss from the descending vasa recta, are difficult to explain on the basic of hydraulic and oncotic forces alone. The osmolality of the contents of descending vasa recta increased between base and tip (delta = 72 +/- 30 mosmol/kg H2O). If the increase in osmolality of plasma in descending vasa recta lags behind that of the adjacent medullary interstitium, a transcapillary osmotic driving force exists favoring water loss from descending vessels. It is concluded that fluid uptake by the inner medullary circulation occurs beyond descending vasa recta in interconnecting capillaries or ascending vasa recta. In our view the most likely interpretation of these results is that fluid movement across vasa recta in the inner medulla is influenced by three forces: those owing to transcapillary differences in osmotic, oncotic, and hydraulic pressures.     

Ultrastructural differences between rat inner medullary descending and ascending vasa recta;

The ultrastructure of rat inner medullary vasa recta was studied by both conventional transmission and freeze-fracture electron microscopy. The identify of descending and ascending vasa recta in the inner medulla was established by tracing outer medullary descending vasa recta and ascending vasa recta into the inner medulla, as well as by the incomplete carbon labeling technique to identify isolated descending vessels or loops. As in the outer medulla, descending vessels possess thick continuous endothelium with pinocytotic vesicles budding off the luminal and basal plasma membranes (more numerous in the latter location), but no fenestrae. Ascending vasa show thin, attenuated endothelium with numerous (500 to 800 A fenestrae bridged by 40 A thick fenestral diaphragms. Intercellular junctions in both vessels are zonulae occludens with usually one, and uncommonly two or three zones of outer leaflet membrane fusion. Intramembranous particles are numerous in endothelial plasma membranes of descending vasa recta; similar particles are much fewer in corresponding ascending vasa recta endothelial plasma membranes. The ultrastructural differences between descending vasa recta and ascending vasa recta may reflect markedly different permeability properties, particularly to macromolecules, and may be relevant to recent functional studies on rat inner medullary vasa recta.     

Minimum urine flow rate during water deprivation: importance of the nonurea versus total osmolality in the inner medulla

Antidiuretic hormone leads to an increase in the permeability for water and urea in the inner medullary collecting duct. Hence, urea may not be an "effective" osmole in the inner medulla during maximal renal water conservation. Accordingly, the purpose of this study was to evaluate whether differences in the rate of urea excretion would influence maximum renal water conservation in humans. In water-deprived rats, the concentration of urea and total osmolality were somewhat higher in the urine exiting the inner medullary collecting duct than in interstitial fluid obtained from the entire papillary tip. Nevertheless, the "nonurea" (total osmolality minus urea in millimolar terms) osmolality was virtually identical in both locations. Chronically fasted human subjects that were water-deprived for 16 h had a lower rate of urea excretion (71 +/- 7 versus 225 +/- 14 mumol/min) and a somewhat lower urine osmolality (745 +/- 53 versus 918 +/- 20 mosmol/kg H2O). Nevertheless, they had identical urine flow rates (0.5 +/- 0.01 and 0.5 +/- 0.02 ml/min, respectively), and their nonurea osmolality also was similar (587 +/- 25 and 475 +/- 14 mosmol/kg H2O, respectively) to the water-deprived normal subjects. The composition of their urine differed in that the principal nonurea osmoles became NH4+ and beta-hydroxybutyrate rather than Na and C1. During water deprivation in normal subjects, the ingestion of urea caused a twofold rise in urine flow rate, a fall in the nonurea osmolality, and a rise in the rate of excretion of nonurea osmoles. The nonurea osmolality of the urine, and presumably the medullary interstitial fluid as well, was inversely related to the urea excretion rate. In chronic fasting, the nature, but not the quantity, of nonurea osmoles changed. The similar minimum urine volume was predictable from an analysis based on nonurea osmole considerations.     

Urea transporter UT3 functions as an efficient water channel. Direct evidence for a common water/urea pathway

A family of molecular urea transporters (UTs) has been identified whose members appear to have an exceptionally high transport turnover rate. To test the hypothesis that urea transport involves passage through an aqueous channel, osmotic water permeability was measured in Xenopus oocytes expressing UTs. The UT3 class of urea transporters functioned as efficient water channels. Quantitative measurement of single channel water permeability (pf) using epitope-tagged rat UTs gave pf (in cm3/s x 10(-14)) of 0.14 +/- 0.11 (UT2) and 1.4 +/- 0.2 (UT3), compared with 6.0 and 2.3 for water channels AQP1 and AQP3, respectively. Relative single channel urea permeabilities (purea) were 1.0 (UT2), 0.44 (UT3), and 0.0 (AQP1). UT3-mediated water and urea transport were weakly temperature-dependent (activation energy <4 kcal/mol), inhibited > 75% by the urea transport inhibitor 1,3-dimethylthiourea, but not inhibited by the water transport inhibitor HgCl2. To test for a common water/urea pore, the urea reflection coefficient (sigmaurea) was measured by independent induced osmosis and solvent drag methods. In UT3-expressing oocytes, the time course of oocyte volume in response to different urea gradients (induced osmosis) gave sigmaurea approximately 0.3 for the UT3 pathway, in agreement with sigmaurea determined by the increase in uptake of [14C]urea during osmotic gradient-induced oocyte swelling (solvent drag). In oocytes of comparable water and urea permeability coexpressing AQP1 (permeable to water, not urea) and UT2 (permeable to urea, not water), sigmaurea = 1. These results indicate that UT3 functions as a urea/water channel utilizing a common aqueous pathway. The water transporting function and low urea reflection coefficient of UT3 in vasa recta may be important for the formation of a concentrated urine by countercurrent exchange in the kidney.     

Location of an inducible nitric oxide synthase mRNA in the normal kidney

An inducible nitric oxide synthase (iNOS) mRNA was found primarily in the outer medulla of normal rat kidney. Identification of the mRNA was based upon the specificity of the oligonucleotide primers used for PCR amplification, PCR-Southern blot analysis and the nucleic acid sequence of the cloned PCR product. In addition to the outer medulla, glomeruli prepared from normal rat kidney contained significant amounts of an iNOS mRNA. These results suggest that there may be tonic influences in the outer medulla of the normal rat kidney resulting in the "steady-state" presence of an iNOS mRNA. Cortical tubules and the inner medulla were found to contain detectable but lesser amounts of the iNOS mRNA. The outer medulla was microdissected into proximal straight tubule (PST), medullary thick ascending limb (MTAL), medullary collecting duct (MCD) and vasa recta bundle (VRB). The iNOS mRNA was found primarily in the MTAL with minor amounts in the MCD and VRB of normal rat kidney. Animals were injected with lipopolysaccharide (LPS) and sacrificed 24 hours later. Treatment with LPS caused at least a 20-fold increase in the amount of iNOS mRNA in the liver or in macrophages isolated from the peritoneum. Endotoxin treatment led to over a 10-fold increase in iNOS mRNA content in glomeruli and the inner medulla. The iNOS mRNA level of the outer medulla was increased two- to threefold due to LPS treatment.     

Autoradiographic localization of vasopressin V1a receptors in the rat kidney using [3H]-SR 49059

Localization and characterization of binding sites of the selective non-peptide vasopressin receptor V1a ligand, [3H]-SR 49059, were investigated in the adult rat kidney by quantitative autoradiography using a fast-detecting radioluminographic phosphor-imaging plate system. [3H]-SR 49059, like the other V1a ligands used, showed a total absence of binding in the papilla, discrete and sparse labeling in the cortex and maximal binding in the outer part of the inner medulla. This labeling seemed to be mainly associated with medullary interstitial cells and vascular elements of the vasa recta. Conversely, [3H]-AVP intensely labeled the V2-enriched medulla-papillary portion of the kidney and, to a lesser extent, the cortical structures. [3H]-SR 49059 binding, quantified in the outer part of the inner medulla in rat kidney sections, was time-dependent, reversible, saturable and a single class of high affinity binding sites (Kd = 1.48 +/- 0.16 nM) was identified. The relative potencies of the reference peptide and non-peptide compounds to inhibit [3H]-SR 49059 binding confirm the V1a nature of the site and the stereospecificity of this binding. Thus, [3H]-SR 49059 allows the mapping and characterization of the V1a receptor population present in the rat kidney. The stability and the highly selective affinity of this non-peptide ligand for rat and human V1a receptors make it a suitable probe for the localization of V1a receptors in organs expressing heterogeneous populations of receptors.     

Vehicle-dependent in situ modification of membrane-controlled drug release

Transmission electron microscopic techniques were used to carry out a quantitative analysis of the density of fenestration in the inner medullary vasa recta of the rat kidney. Measurements were made at 200 microns intervals from the tip to the base of the papilla (1800 microns from the tip). Fenestral diaphragms were estimated to be 65.4 +/- 0.78 nm in diameter (mean +/- S.E.M.), and were arranged in plaques with a mean interfenestral distance of 114.8 +/- 2.6 nm. Near the tip of the papilla there was no correlation between vessel size and degree of fenestration; density of fenestration, however, began to decrease about 1400 microns from the tip. The ratio of fenestrated to non-fenestrated profiles of vasa recta was found to be linear with respect to distance from the tip (r = 0.991), with values ranging from about 40:1 near the tip to 2:1 near the base of the papilla. We have estimated the proportion of the total surface area of a fenestrated vasa recta occupied by fenestral diaphragms to be 0.057 at 1000 microns from the tip. The total potential conductance (K) of a 200 microns segment of fenestrated vessel at 1000 microns from the tip was calculated to be 0.319 microns 3 s-1 cmH2O-1, giving a hydraulic conductivity (Lp) of 0.030 micron s-1 cmH2O-1. We have also examined the reverse question of the conductance of a single fenestra if all the fluid flux across the vessel wall occurred through the fenestrae and none via the intercellular clefts or water channels; single fenestral conductance was estimated to be 1.94 x 10(-3) microns 3 s-1 cmH2O-1.     

Renal tubular and vascular urea transporters: influence of antidiuretic hormone on messenger RNA expression in Brattleboro rats

In the kidney, facilitated urea transport in precise vascular and tubular structures is mainly involved in water conservation. Three urea transporters have been cloned: UT2-long expressed in terminal inner medullary collecting duct (IMCD), UT2-short expressed in thin descending limb, and UT11 in descending vasa recta. The effect of arginine vasopressin (AVP) administration on mRNA expression of these three transporters was examined in Brattleboro rats with diabetes insipidus. V2 effects were discriminated from combined V1 + V2 effects by comparing treatments with 1-deamino-8-D-AVP (dDAVP) (selective V2 agonism) and AVP (V1 and V2 agonism). Acute and chronic treatments were studied. Abundance of specific mRNA was assessed by quantitative Northern blot analysis of RNA extracted from two regions of inner stripe of outer medulla and from two regions of inner medulla (IM). The results show that mRNA of these urea transporters are differently regulated by AVP. (1) Long-term treatment with either AVP or dDAVP does not alter UT2-long mRNA in tip IM (terminal IMCD) except for a transient initial decrease. (2) Unlike AVP, dDAVP induces the appearance of significant expression of UT2-long mRNA in base IM (initial IMCD), indicating a major V2 effect. (3) UT2-short mRNA in deep inner stripe of outer medulla and base IM (thin descending limb of short and long loops, respectively) is progressively upregulated with duration of AVP or dDAVP treatment. (4) The much higher changes in UT2-long and UT2-short induced by dDAVP compared with AVP suggest that they are dependent mainly on V2 agonism, and likely attenuated by V1 agonism. (5) UT11 mRNA expression in tip IM is equally depressed by AVP and dDAVP, indicating that this vascular transporter is also influenced by AVP and/or urine-concentrating activity, via an indirect mechanism that remains to be determined.     

Excretion in mammals: role of the renal pelvis in the modification of the urinary concentration and composition

The mammalian renal pelvis has previously been regarded as having no physiological function other than that of a receptacle for the urine before it moves through the ureter. It has long been known that the renal pelvis in mammals shows elaborate extensions that bring the urine in intimate contact with outer and inner medullary tissue. The epithelium covering these areas is of a type that indicates that transport of solutes and water can take place across it. Physiological studies have shown that urea and water readily move across the renal papillary epithelium. The pronounced ability of ruminants to conserve urea when placed on a low protein diet coincides with a highly developed renal pelvis with specialized fornices and secondary pouches. It is suggested that urea conservation in low protein animals takes place partly in the renal pelvic extensions where urea is returned to the blood. A hypothesis is also proposed for the concentrating mechanism in which recycling of urea from the pelvic urine across the papillary epithelium plays an important role.     

Impact of cyclo-oxygenase blockade on juxtamedullary microvascular responses to angiotensin II in rat kidney

1. Experiments were designed to evaluate the hypothesis that cyclo-oxygenase products modulate the influence of angiotensin II (AII) on the renal juxtamedullary microvasculature of enalaprilat-treated rats. 2. The in vitro blood-perfused juxtamedullary nephron technique was utilized to provide access to afferent arterioles, efferent arterioles and descending vasa recta located in the outer stripe of the outer medulla. 3. Baseline afferent arteriolar diameter was 20.8 +/- 1.9 microns in kidneys subjected to cyclo-oxygenase blockade (1 mumol/L piroxicam), a value significantly lower than that observed in untreated kidneys (26.1 +/- 1.0 microns). Baseline diameters of efferent arterioles and outer medullary descending vasa recta did not differ between untreated and piroxicam-treated groups. 4. Topical application of 1 nmol/L AII reduced blood flow through outer medullary descending vasa recta by 22 +/- 6% in untreated kidneys and by 24 +/- 7% in piroxicam-treated kidneys. 5. In untreated kidneys, AII (0.01-100 nmol/L) produced concentration-dependent afferent and efferent arteriolar constrictor responses of similar magnitudes. Neither afferent nor efferent arteriolar AII responsiveness was significantly altered in piroxicam-treated kidneys, although afferent responses exceeded efferent responses at AII concentrations > or = 10 nmol/L. 6. We conclude that endogenous cyclo-oxygenase products exert a vasodilator influence on juxtamedullary afferent arterioles under baseline conditions. Although cyclo-oxygenase inhibition had little effect on juxtamedullary microvascular responses to AII, the response to high AII concentrations may be modulated by cyclo-oxygenase products in a manner which delicately alters the relative influence of the peptide on pre- vs postglomerular resistances.     

The pathogenesis of Graves'' disease

The renal countercurrent bundles of elasmobranch fish were studied by light and electron microscopy. The kidneys of the lesser spotted dogfish, Scyliorhinus caniculus Blainville, and the little skate, Raja erinacea Mitchill, were investigated. Three-dimensional reconstruction with computer assistance revealed the spatial association of the renal tubular segments and their relationships to each other, as well as to the microvasculature. Regular association between structures was assessed by quantification of contact points on histological sections. The bundles contain a hairpin loop of neck segment and the beginning of the proximal tubule, PIa. The limbs of this loop closely adhere to each other, and a second loop (the early distal tubule) coils around the first loop at the tip of the bundle. The collecting tubule runs between the two loops, and merges with the collecting duct inside the end portion of the bundle. A single lymph capillary-like vessel originates from a few blind-ended rami at the tip of the bundle and runs in close contact with the collecting tubule along the entire bundle. This central vessel merges via several side branches with the venous sinusoid capillaries of the peritubular blood circulation. Thereby the central vessel provides a channel for convective flow of NaCl-rich fluid unidirectionally to the venous portal system of the mesial tissue zone of the kidney. By the close spatial arrangement of the collecting tubule and the central vessel countercurrent exchange of urea from the collecting tubule urine to the fluid in the central vessel is feasible. Thus, the spatial organisation of renal tubular segments and the central vessel is considered to represent the morphological correlate to urea retention by the kidney of Elasmobranchii.     

Entactin-2: a new member of basement membrane protein with high homology to entactin/nidogen

Metabolites in proton chemical exchange with water were detected via the water proton signal using saturation transfer techniques in model systems and biological tissues. The metabolites were selectively saturated and the resulting decrease in the much larger water proton pool was used to monitor the metabolite. This indirect detection scheme can result in a several orders of magnitude increase in sensitivity for metabolites over direct detection methods. A control irradiation scheme was devised to compensate for macromolecular/water magnetization transfer. Using this approach, significant chemical exchange regions at approximately 1 and 2.5 ppm were detected in kidney medulla. Using a difference imaging technique between a control irradiation above (-1.74 ppm) and below (+1.74 ppm) the water resonance, a chemical exchange image of the kidney was calculated. These data revealed a linear gradient of chemical exchange increasing from the cortex to the medulla. Studies on medullary acid extracts and urine revealed that the exchange observed in the kidney was predominantly with low molecular weight metabolites. Urea (1 ppm) was identified as contributing to the kidney/urine chemical exchange; however, other unidentified metabolites may also contribute to this effect. These studies demonstrate that tissue metabolites can be detected and imaged via the water protons using the signal amplification properties of saturation transfer in the presence of water/macromolecule magnetization transfer.     

Role of aquaporin water channels in kidney and lung

Several aquaporin-type water channels are expressed in mammalian kidney and lung: AQP1 in lung microvessels and kidney proximal tubule, thin descending limb of Henle, and vasa recta; AQP2 in apical membrane of collecting duct epithelium; AQP3 and AQP4 in basolateral membranes of airway and collecting duct epithelium; and AQP5 in alveolar epithelium. Novel quantitative fluorescence methods demonstrated very high water permeabilities of the alveolar epithelial and endothelial barriers, and moderately high water permeability across distal airways. In the kidney, water permeability is high in proximal tubule and thin descending limb of Henle, and regulated by vasopressin in collecting duct. The author's laboratory has studied the role of aquaporins in organ physiology using transgenic knockout mice lacking specific aquaporins. AQP1 null mice are mildly growth-retarded, manifest a severe urinary concentrating defect, and have reduced water permeability between airspace and capillary compartments. AQP4 null mice appear normal grossly except for a mild defect in maximum urinary concentrating ability. AQP2-deficient humans have hereditary non-X-linked nephrogenic diabetes insipidus (NDI). In transfected mammalian cells, many NDI-causing AQP2 mutants are retained in the endoplasmic reticulum. The author's laboratory has found that "chemical chaperones," that is, small compounds that promote protein folding in vitro, are able to correct defective AQP2 trafficking in cell culture models. The transgenic mouse and mammalian cell models are thus beginning to provide clues about the role of aquaporins in normal physiology and disease.     

Responses of reindeer to water loading, water restriction and ADH

Two female reindeer were hydrated by administration of (10% of b.wt.) water into the rumen. The diuretic response was very fast and strong but the urea and electrolyte excretion were little affected. Dehydration was carried out by not giving the reindeer water for 48 h. This water deprivation caused a loss of up to 20% of their body weight. The urine osmolality did not exceed 840 mosm/kg H2O, although the plasma osmolality rose from 300 to 346 and 368 mosm/kg H2O respectively. The plasma and urine urea concentrations were elevated during dehydration, while the urine urea excretion did not increase. Urine sodium concentration did not increase. When the urine flow rate, after two days of water deprivation, decreased to half of the original, the urine Na+ concentrations, instead of increasing, went down to half of the original. So did the potassium excretion. When ADH was injected intravenously into hydrated animals a dose of 30 mU of ADH was needed to induce antidiuresis or increased excretion of potassium. The resistance to ADH and the low relative thickness of the medulla confirm the limited capacity of reindeer kidney to concentrate urine or to excrete a solute load. On the other hand, reindeer is able rapidly to excrete surplus water without affecting the electrolyte or nitrogen balance.     

Urothelial changes of the renal papillae in Sprague-Dawley rats induced by long term feeding of phenacetin

Thirty female Sprague-Dawley rats were fed 0.535 per cent phenacetin in the diet for up to 110 weeks. Twenty-six of these rats developed urothelial hyperplasia, partly papillary, of the renal papillae. Twenty-eight rats showed dilatation of the vasa recta frequently associated with thrombus formation and calcification. One phenacetin fed rat had epithelial hyperplasia associated with chronic pyelitis. In 2 of the 30 control rats urothelial hyperplasia was found to be associated with chronic pyelitis. The hyperplastic urothelial changes and vascular changes were often, but not always, present simultaneously. One control rat developed a mammary carcinoma, as compared with 5 rats in the phenacetin group. Four phenacetin fed rats developed carcinoma of the ear duct. The results of the present investigation provide evidence that phenacetin can induce proliferative lesions of the urothelium of the rat renal pelvis with weak carcinogenic activity in the ear duct and mammary glands.     

Results of antireflux surgery in infants with vesicoureteral reflux

The mechanism underlying the reduced Cu status in rats fed on a high-sulphide diet was investigated. Male rats aged 6 weeks were fed ad libitum on purified diets containing either 0 or 500 mg S2-/kg and demineralized water for a period of 2 weeks. The high-sulphide diet had no effect on feed intake, body-weight gain or weight of liver and kidney but significantly reduced Cu concentrations in plasma and kidney. Biliary Cu excretion was decreased significantly in rats fed on the high-sulphide diet. Apparent Cu absorption (Cu intake-faecal Cu) and true Cu absorption (Cu intake-(faecal Cu-biliary Cu)) were significantly lowered after sulphide feeding for 2 weeks. Rats fed on the high-sulphide diet excreted less Cu in urine than did the controls. We conclude that high sulphide intake reduces Cu status in rats through inhibition of Cu absorption which is reflected by a decrease in biliary Cu excretion as a secondary feature.