Urea uptake and translocation in toad urinary bladder: the effect of antidiuretic hormone.

The uptake of C14-urea into everted and noneverted bladder sacs was compared, over short time periods (up to 2 min), with the transepithelial urea fluxes. This method allowed the study of the time course of urea uptake and distribution, while previously this problem was only studied in steady-state conditions. When mucosal uptake was studied no accumulation of C14-urea inside the tissue was observed, indicating that the mucosal border could be the limiting step. Comparative studies of urea and inulin uptake from the serosal side showed that urea equilibrated with the water epithelial cells in less than 30 sec. This accumulation suggested again that the mucosal border is an effective barrier for urea translocation. The kinetics of the increase in urea permeability induced by antidiuretic hormone was also studied and it was similar (T1/2:4.3 min) to the kinetics of the increase in water permeability induced by the hormone (T1/2:5.6 min). A strong parallelism was also observed between the time course of the increases in water and urea permeabilities induced by medium hypertonicity (T1/2 25 and 26 min, respectively). The values obtained for the permeability coefficient ktrans), either at rest or under ADH were similar to those previously reported employing steady-state techniques (28+/-8 and 432+/-25 cm-sec-1-10(-7), respectively).     

Differential handling of urea and its analogues suggests carrier-mediated urea excretion in freshwater rainbow trout

The possible presence of urea transport mechanisms in the gill and kidney of the freshwater rainbow trout (Oncorhynchus mykiss) was investigated in vivo by comparing the branchial and renal handling of analogues acetamide and thiourea with the handling of urea. Trout were fitted with indwelling dorsal aortic catheters and urinary catheters and injected with an isosmotic dose of [(14)C]-labeled urea analogue (acetamide or thiourea) calculated to bring plasma analogue concentrations close to plasma urea concentrations. Urea and analogue concentrations were significantly greater in the urine than in the plasma. Branchial clearance rate of acetamide was only 48% of urea clearance, whereas the clearance of thiourea was only 22%, a pattern that was also observed in branchial uptake of these substances and was similar to our previous observations in toadfish and midshipmen. The renal secretion clearance rates of urea and acetamide were similar, and on average, both substances were secreted on a net basis, although reabsorption did occur in some cases. In contrast, thiourea was neither reabsorbed nor secreted by the kidney tubule. The secretion clearance rates of both acetamide and urea were well correlated with the secretion clearance rates of Na(+), Cl(-), and water, whereas there was no relationship between thiourea and these substances. The pattern of acetamide, thiourea, and urea handling by the gill of the trout is similar to that found in the gills of the midshipman and the gulf toadfish and strongly suggests the presence of a UT-type facilitated diffusion urea transport mechanism. The pattern of differential handling in the kidney is unlike that in the gill and also unlike that in the kidney of the midshipman and the gulf toadfish, suggesting a different mechanism. In addition, renal urea secretion occurs against a concentration gradient, suggesting the involvement of an active transport mechanism.     

Branchial and renal excretion of urea and urea analogues in the plainfin midshipman,Porichthys notatus

This study investigated whether urea transport mechanisms were present in the gills of the ammoniotelic plainfin midshipman (Porichthys notatus), similar to those recently documented in its ureotelic relative (family Batrachoididae), the gulf toadfish (Opsanus beta). Midshipmen were fitted with internal urinary and caudal artery catheters for repetitive sampling of urine and blood in experiments and radiolabeled urea analogues ([(14)C]-thiourea and [(14)C]-acetamide) were used to evaluate the handling of these substances. Isosmotically balanced infusions of urea were used to raise plasma and urine urea concentrations to levels surpassing physiological levels by 8.5-fold and 6.4-fold, respectively. Despite these high urea levels, there was no observable transport maximum in either renal or branchial urea excretion rate, a result mirrored by the total uptake of fish exposed to a range of environmental urea concentrations. Permeability to urea appeared to be symmetrical in the two directions. At comparable plasma concentrations the branchial clearance rate of acetamide was 74% that of urea while branchial clearance rate of thiourea was 55% that of urea. For influx, the comparable values were 60% and 36%, indicating the same pattern. In contrast, the secretion clearance rate of acetamide by the kidney was 56% that of urea while the rate of thiourea secretion clearance was 137% greater than that of urea, with both urea and thiourea being more concentrated in the urine than in the plasma. In addition, the secretion clearance rates of thiourea and urea were significantly greater than those of water and Cl(-), whereas acetamide, water and Cl(-) were found equally in the plasma and urine, appearing to passively equilibrate between the two fluids. Based on our findings, there appear to be two distinct transport mechanisms involved in urea excretion in the plainfin midshipmen, one in the gill (a facilitated diffusion type transporter) and one in the kidney (an active transport mechanism), each of which does not saturate even at plasma urea concentrations that greatly exceed physiological levels. These transporters appear to be similar to those in the midshipman's ureotelic relative, the gulf toadfish.     

Urea uptake and translocation in toad urinary bladder: The effect of antidiuretic hormone

Summary The uptake of C¹⁴-urea into everted and noneverted bladder sacs was compared, over short time periods (up to 2 min), with the transepithelial urea fluxes. This method allowed the study of the time course of urea uptake and distribution, while previously this problem was only studied in steady-state conditions. When mucosal uptake was studied no accumulation of C¹⁴-urea inside the tissue was observed, indicating that the mucosal border could be the limiting step. Comparative studies of urea and inulin uptake from the serosal side showed that urea equilibrated with the water epithelial cells in less than 30 sec. This accumulation suggested again that the mucosal border is an effective barrier for urea translocation. The kinetics of the increase in urea permeability induced by antidiuretic hormone was also studied and it was similar (T1/2:4.3 min) to the kinetics of the increase in water permeability induced by the hormone (T1/2:5.6 min). A strong parallelism was also observed between the time course of the increases in water and urea permeabilities induced by medium hypertonicity (T1/2 25 and 26 min, respectively). The values obtained for the permeability coefficientk _trans), either at rest or under ADH were similar to those previously reported employing steady-state techniques (28±8 and 432±25 cm·sec^–1·10^–7, respectively).     

Role of substance P in water homeostasis.

The effect of the naturally occurring peptide substance P on release of antidiuretic hormone (ADH) was studied in anesthetized dogs. Intravenous infusions of substance P in doses of 0.5, 5.0, and 50 ng/kg/min increased plasma concentrations of ADH in a dose-related fashion. At the two low doses, this increase occured in the absence of changes in urine volume, sodium excretion, free water clearance, and urinary cyclic AMP excretion. In addition, when substance P was administered in a concentration of 0.5 ng/kg/min, plasma levels of ADH were increased even though blood pressure did not change, suggesting that substance P may release antidiuretic hormone by a direct mechanism. Intrarenal infusions at a rate of 0.5 and 5 ng/kg/min caused dose-related decreases in free water clearance and significant increases in urinary cyclic AMP excretion. These data suggest that substabce P may play an important role in the regulation of water balance.     

Selective fixation with glutaraldehyde of ADH-induced urea permeability sites in toad bladder

Toad bladders exposed to vasopressin (ADH) and then fixed on the mucosal surface with 1% glutaraldehyde were highly permeable to water and to urea compared to control bladders fixed in the absence of hormone. When identical conditions of fixation were were used, but the concentration of glutaraldehyde was decreased to 0.25%, the ADH-induced increase in membrane permeability to urea was preserved whereas water permeability was not. About 74% of the hormone-induced urea permeability sites were preserved by glutaraldehyde and were stable to changes in temperature as suggested by a constant value for the activation energy of urea movement of 5.4 kcal/mole (4-33 degrees C). In other studies bladders were exposed at low temperatures to 0.17% glutaraldehyde applied either to the serosal or the mucosal surface. The ADH-induced increase in membrane permeability to urea, bulk water, and tritiated water was well preserved with serosal fixation, but not with mucosal fixation. The observation that the urea pathway can be selectively preserved with 0.25% glutaraldehyde applied to the mucosa indicates that this structure is more accessible and (or) more sensitive to low-dose glutaraldehyde than is the ADH-induced water pathway. The observation that glutaraldehyde is more effective in stabilizing the ADH-induced urea channels from the serosal than from the mucosal surface indicates that these channels are not fixed at the extracellular surface of the apical plasma membrane. It appears, rather, that glutaraldehyde exerts its effects from an intracellular position, where it cross-links components of the urea channels at the cytoplasmic surface of the apical membrane and (or) inactivates the intracellular machinery responsible for the removal or dispersal of the ADH-induced urea permeability sites.     

Effect of reagents of protein functional groups on the ADH-induced urea facilitated transport across toad urinary bladder

1--The mechanism of the vasopressin-induced, facilitated transport across toad urinary bladder was studied by treating the luminal membrane of the epithelium with the following reagents of protein functional groups: NEM (SH groups), SITS (amino groups), EEDQ (carboxylic groups), DEPC (histidine). 2--Treatment of the luminal side of the epithelium by NEM strongly inhibits the ADH-induced urea transport, leaving unmodified the effect of the hormone on the flux of antipyrine, a lipid soluble molecule. These results confirm the hypothesis that the urea carrier is of proteic nature. 3--Treatment of the luminal side by SITS strongly inhibits ADH action on urea and antipyrine permeability; thus this effect can be considered rather unspecific. 4--On the contrary the EEDQ effect is more specific; in fact treatment of the luminal side by EEDQ strongly inhibits ADH effect on the permeability of urea, slightly increasing the ADH effect on that of antipyrine. 5--Finally, the luminal treatment by diethylpyrocarbonate inhibits almost completely the ADH action on the urea fluxes, slightly increasing the hormone effect on the antipyrine ones. 6--Based on these results we conclude that carboxylic groups and the imidazolic ring are more important than the amino groups in determining the urea transport across toad bladder, in the presence of ADH.     

Comparative effect of metals on antidiuretic hormone induced transport in toad bladder: specificity of mercuric inhibition of water channels

We previously reported that HgCl₂ inhibits water and urea flux in tissues fixed with glutaraldehyde after antidiuretic hormone (ADH) stimulation and suggested that the ADH-induced water channel may share characteristics of the red blood cell and proximal tubule water transport pathway. To determine the specificity of mercury's action, we examined the effect of numerous other metals. In tissues fixed after ADH stimulation, water flow and urea and sucrose permeabilities are maintained from mucosal bath pH 2.5 through pH 12. Several metals including Ba, Co, Fe, Sr and Zn did not alter flux. Al, Cd, La, Li, Pb and U inhibited urea permeability but not water flow. At pH 2.8, Cu inhibited water flow by 30% and urea permeability by 50%. At pH 4.9–7.4, Cu inhibited urea permeability but not water flow. At pH 3.0, Pt inhibited flow in ADH-pretreated tissues. The inhibitory effect was not present at pH>3.0. At pH<3.0, Au inhibited flow by 90% in tissues fixed after pretreatment with ADH but increased the permeability of tissues fixed in the absence of ADH. Ag inhibited flow by 70% but also increased sucrose, urea, and basal permeabilities. This suggests that Ag and Au disrupt epithelial integrity. These results indicate that at physiologic pH, the ADH-induced water channel is specifically blocked by Hg but not by other metals. This specificity may reflect the presence of a large number of sulfhydryl groups in the water channel.     

Developmental profile and tissue distribution of Drosophila alcohol dehydrogenase: an immunochemical analysis with monoclonal antibodies.

To analyze Drosophila alcohol dehydrogenase gene (Adh) expression and tissue distribution at various developmental stages, we devised several immunochemical techniques making use of monoclonal antibodies against Drosophila alcohol dehydrogenase (ADH), which had been obtained previously. We here report their application to analyze the expression of Adh in a wild-type strain of D. melanogaster. s-ELISA tests were performed to evaluate fluctuations in ADH content and specific activity during development in individual organs as well as in whole individuals. In all cases, ADH specific activity appeared to be quite constant, which implies that variations in enzyme activity reflect differences in protein content. Immunoblottings of crude homogenates revealed immunoreactive low relative molecular mass peptides in addition to the 27 KD monomeric band, showing a conserved banding pattern in different organs and developmental stages. Immunohistochemical assays on whole organs were used to analyze the general pattern of ADH distribution. Immunoperoxidase staining of cryosections proved to be of crucial relevance, as it yielded full details of the tissue localization of ADH within the ADH-positive organs. We have shown not only that ADH displays a specific distribution in some organs but also that the enzyme is restricted to certain cell types.     

On the role of calcium in the mechanism of ADH action

With an increased influx of Ca2+ in the cytoplasm, the response of cells to ADH in the urinary bladder of the frog was lowered by addition of ionophore A23187 from the side of the basolateral cell membrane, but inhibited when it was added from the apical cell membrane. The removal of calcium by EGTA from the serosal surface was accompanied by a sharp increase of osmotic permeability not only to water, but also to inulin; while when calcium was removed from the mucosal surface of the urinary bladder, osmotic permeability was not changed. After being added to the Ringer solution from the outer surface of the apical cell membrane, the inhibitors of Ca2+ channels (verapamil, Ni2+, Mn2+, Co2+) decreased the effect of ADH. These data indicate that Ca2+ applied onto the outer surface of apical plasma membrane plays an important role in the action of ADH.     

Urea‐induced binding between diclofenac sodium and bovine serum albumin: a spectroscopic insight

We investigated the interaction of diclofenac sodium (Dic.Na) with bovine serum albumin (BSA) in the absence and presence of urea using different spectroscopic techniques. A fluorescence quenching study revealed that the Stern–Volmer quenching constant decreases in the presence of urea, decreasing further at higher urea concentrations. The binding constant and number of binding sites were also evaluated for the BSA–Dic.Na interaction system in the absence and presence of urea using a modified Stern–Volmer equation. The binding constant is greater at high urea concentrations, as shown by the fluorescence results. In addition, for the BSA–Dic.Na interaction system, a static quenching mechanism was observed, which was further confirmed using time‐resolved fluorescence spectroscopy. UV–vis spectroscopy provided information about the formation of a complex between BSA and Dic.Na. Circular dichroism was carried out to explain the conformational changes in BSA induced by Dic.Na in the absence and presence of urea. The presence of urea reduced the α‐helical content of BSA as the Dic.Na concentration varied. The distance r between the donor (BSA) and acceptor (Dic.Na) was also obtained in the absence and presence of urea, using fluorescence resonance energy transfer. Copyright © 2015 John Wiley & Sons, Ltd.     

Endocrine concomitants of sweating and sweat depression

The effect of humid heat (Ta = 43 degrees C, Pa = 32 Torr) on sweat rate, plasma renin activity and plasma levels of aldosterone and antidiuretic hormone (ADH) was studied in four male subjects before and after repeated heat exposures. Over-sweating and sweat drippage followed by hidromeiosis were observed in three subjects during initial heat exposure. With repeated humid heat exposures increased sweat rates were accompanied by a more intense sweat depression (hidromeiosis) in all four subjects. In our conditions, no changes in plasma levels of aldosterone and ADH or plasma renin activity were observed with hidromeiosis. Plasma renin activity was slightly depressed by repeated exposures, whereas plasma volumes were enhanced, with no significant changes in plasma Na or K. The results suggest that neither ADH nor the components of the renin-angiotensin aldosterone system are involved in the hidromeiotic phenomenon.     

Permeability of the Isolated Toad Bladder to Solutes and Its Modification by Vasopressin

Measurements have been made of the permeability of the isolated urinary bladder of the toad to a number of small solute molecules, in the presence and absence of vasopressin. Vasopressin has a strikingly specific effect on increasing permeability of the bladder to a group of small, uncharged amides and alcohols while penetration by other small molecules and ions is unaffected. The movement of urea is passive, as indicated by equal flux rates in the two directions. The reflection coefficients for chloride and thiourea indicate a high degree of impermeability of the bladder to these solutes even in the presence of large net movements of water. The low concentration of thiourea in the tissue water when this compound is added to the mucosal bathing medium indicates that the major permeability barrier to thiourea is at the mucosal surface of the bladder. The findings can be accounted for by a double permeability barrier consisting of a fine selective diffusion barrier and a porous barrier in series. The former would constitute the permeability barrier to most small solutes while the latter would be the rate-limiting barrier for water and the amides. It would be the porous barrier which is affected by vasopressin. Reasons are presented which require both barriers to be contained in or near the plasma membrane at the mucosal surface of the bladder.     

Rate of hydrolysis of urea as influenced by thiourea and pellet size

Summary Two incubation experiments and a number of field experiments were conducted to determine the effect of soil moisture tension, pellet size and addition of thiourea to urea on the rate of urea hydrolysis. In the incubation experiments at 20°C, the rate of hydrolysis of urea increased from 15 bar to 1/3 bar soil moisture tension, with the largest change (doubling) occurring from 15 bar to 7 bar moisture tension. Increasing pellet size reduced the rate of urea hydrolysis by about 12% with urea pellets weighing 0.21 g as compared to 0.01 g urea pellets after 114h. When thiourea (a metabolic inhibitor) was pelleted with urea in a ratio of two parts urea and one part thiourea, the rate of hydrolysis was halved.In a field experiment, the addition of thiourea to urea and increasing pellet size suppressed the rate of urea hydrolysis considerably for 8 days. The amount of urea hydrolyzed with urea+thiourea (21) pellets weighing 2.51 g was one-fourth of the amount of urea hydrolyzed with 0.01 g pellets of urea alone. In the other six field experiments which were set out in October, only 22% to 39% of urea +thiourea (21) was hydrolyzed at two weeks after application, while almost all of the urea was hydrolyzed when it was mixed into the soil without an inhibitor.Unter our field conditions, we would estimate that the hydrolysis of urea can be inhibited for at least one week. The inhibition of urea hydrolysis appears to be great enough that the problems encountered from the rapid hydrolysis of urea, wherever these occur, may be reduced by combined use of thiourea and either increased pellet size or band placement.     

Hormonal regulation of a plasma membrane phosphodiesterase in differentiating granulosa cells. Reciprocal actions of follicle-stimulating hormone and a gonadotropin-releasing hormone agonist on cAMP degradation

The activity of a plasma membrane cAMP-phosphodiesterase in cultured ovarian granulosa cells was regulated by follicle-stimulating hormone (FSH) and the gonadotropin-releasing hormone (GnRH) agonist [D-Ala6]des-Gly10-GnRH N-ethylamide (GnRHa). Degradation of cAMP was similar in cultures treated with FSH alone or FSH plus GnRHa when the labeled cyclic nucleotide was added from 24 to 42 h of culture. However, at 48 h and subsequent times of incubation, cAMP phosphodiesterase activity was significantly higher in cells incubated with FSH plus GnRHa. Phosphodiesterase activity was progressively increased by GnRHa concentrations between 10(-13) and 10(-10) M, and was maximally stimulated by 10(-9) M GnRHa. In comparison with control cells, FSH lowered the Vmax of cAMP catabolism by the high (1 microM cAMP substrate) and the low (50 microM) affinity phosphodiesterase, while GnRHa raised enzyme activity toward control levels. These actions of FSH and GnRHa were specific for a plasma membrane phosphodiesterase that was accessible to extracellular cAMP, since extracellular substrate was hydrolyzed, no intracellular uptake of [3H]cAMP was observed, and only a small fraction (10%) of cAMP was catabolized in the incubation medium in the absence of cells. Further, the actions of FSH and GnRHa on the membrane enzyme were the opposite of those observed when total phosphodiesterase activity was measured in cellular sonicates. Hormonal changes in phosphodiesterase activity were not due to leakage of the enzyme from damaged cells since a constant percentage of cAMP hydrolysis in the medium was observed during culture. Analysis of cAMP catabolites in granulosa cells indicated that the phosphodiesterase reaction product, 5'-AMP, was rapidly converted to adenosine by a plasma membrane 5'-nucleotidase, independent of the cellular hormonal status. These results indicate that the opposing actions of FSH and GnRHa upon granulosa cell differentiation include modulation of cAMP degradation at the plasma membrane level.     

Role of antidiuretic hormone in hyponatremia in patients with isolated adrenocorticotropic hormone deficiency.

We found symptomatic hyponatremia in four elderly patients in which serum sodium (Na) levels ranged from 101 to 122 mEq/l. All 4 patients had low levels of plasma adrenocorticotropic hormone (ACTH), serum cortisol, and urinary excretion of 17-OHCS, and poor responses of ACTH to exogenous insulin and antidiuretic hormone (ADH). Other pituitary hormones were all normal. They were therefore diagnosed as having isolated ACTH deficiency. Plasma ADH was relatively high despite hypoosmolality which was associated with the hyponatremia. Water loading test revealed impaired water excretion and poor suppression of plasma ADH. Replacement with 20-30 mg hydrocortisone completely restored the serum Na level and restored the plasma ADH level to the normal range in all 4 patients. Other factors such as decreased glomerular filtration, enhanced urinary Na loss and decreased Na intake were also included. These results indicate that there is marked hyponatremia and that in the presence of hypoosmolality the sustained secretion of ADH is the key factor in causing the impaired water excretion and hyponatremia in isolated ACTH deficiency.     

Tissue osmolytes and body fluid compartments in the toad Bufo viridis under simulated terrestrial conditions

Summary Toads (Bufo viridis) were kept on soil without access to free water (simulated terrestrial conditions) for over 12 weeks. Body water compartments were estimated using the dilution method (inulin and Evans Blue). They were found to remain fairly constant after a period of adjustment which lasted 1–2 weeks. In particular, plasma volume was closely controlled. Plasma osmolarity increased to over 1000 mOsm · 1^–1 accompanying a large increase in its urea concentration. NaCl also increased, while potassium remained constant. Tissue (liver and skeletal muscle) water content did not change much and electrolytes were kept constant. Tissue water urea concentration seemed to equilibrate with that of the plasma. Urine osmolarity, which was hypotonic during water access, became nearly isosmotic and correlated with the plasma following transfer onto soil. Urine urea concentration correlated with the plasma in the terrestrial conditions, potassium was greatly elevated, sodium increased to some extent, and chloride hardly changed. The efficient osmoregulatory mechanisms for the control of distribution of body water sustain normal physiological functions.     

Comparative transport efficiencies of urea analogues through urea transporter UT-B

Expression of urea transporter UT-B confers high urea permeability to mammalian erythrocytes. Erythrocyte membranes also permeate various urea analogues, suggesting common transport pathways for urea and structurally similar solutes. In this study, we examined UT-B-facilitated passage of urea analogues and other neutral small solutes by comparing transport properties of wildtype to UT-B-deficient mouse erythrocytes. Stopped-flow light-scattering measurements indicated high UT-B permeability to urea and chemical analogues formamide, acetamide, methylurea, methylformamide, ammonium carbamate, and acrylamide, each with P(s)>5.0 x 10(-6) cm/s at 10 degrees C. UT-B genetic knockout and phloretin treatment of wildtype erythrocytes similarly reduced urea analogue permeabilities. Strong temperature dependencies of formamide, acetamide, acrylamide and butyramide transport across UT-B-null membranes (E(a)>10 kcal/mol) suggested efficient diffusion of these amides across lipid bilayers. Urea analogues dimethylurea, acryalmide, methylurea, thiourea and methylformamide inhibited UT-B-mediated urea transport by >60% in the absence of transmembrane analogue gradients, supporting a pore-blocking mechanism of UT-B inhibition. Differential transport efficiencies of urea and its analogues through UT-B provide insight into chemical interactions between neutral solutes and the UT-B pore.     

Isotopic studies of urea metabolism in rabbits

1. The half-life of [¹⁵N]urea was found to be significantly longer than that of [¹⁴C]urea injected at the same time, the differences being due to endogenous catabolism of urea, which is accompanied by little or no reutilization of ¹⁴C but is approx. 20% for ¹⁵N. [¹⁵N]Urea therefore appears to be valueless as an indicator of nitrogen metabolism unless the extents of endogenous catabolism of urea and of fractional reutilization of ¹⁵N can be separately estimated. 2. Though measurements of the radioactivity of expired ¹⁴CO₂ confirmed the existence of considerable urea catabolism these could not be used for quantitative assessments. 3. Alternative graphical methods based on [¹⁴C]urea specific activities in plasma and urine samples were used to calculate the fraction of urea production that is excreted. Values by the two methods were in good agreement and showed that some animals excrete less than half the urea that they produce. 4. Specific activity differences between simultaneous samples of urinary and plasma urea reflect the presence of a pool of urea in the kidney that is not in equilibrium with the body urea pool. Calculations indicate the presence of urea in the kidney that in some cases may represent as much as 15% of the body pool, and in two animals in which post-mortem renal analyses were performed the masses of urea found agreed closely with the calculated values. 5. A model for urea metabolism is proposed that includes this pool in the excretory pathway. The related theory is shown to be adequate to explain the shape of the specific activity curves of urinary urea from the time of injection and the constant delay of the specific activity of urinary urea, relative to that of plasma urea, that is observed after a short preliminary equilibration period. 6. The body urea pool was calculated from the activity retained at 1·5hr. by excluding renal activity and the corrected specific activity of plasma urea at the same time. The urea pool was calculated to be distributed at the plasma concentration in a substantially smaller water volume than that found by injecting tritiated water in five animals. Reasons for this are discussed. 7. Urea synthesis rates calculated from the pool values are in close agreement with rates calculated from the mass of urea recovered in the urine and the fraction of newly synthesized urea that is excreted.     

Chemical modification of bovine heart mitochondrial malate dehydrogenase. Selective modification of cysteine and histidine.

Bovine mitochondrial malate dehydrogenase (EC 1.1.1.37) was inactivated by the specific modifications of a single histidine residue upon reaction with iodoacetamide. NADH protected against this loss of activity and reaction with the histidine residue, suggesting that the histidine is at the NADH binding site. N-Ethylmaleimide also modified the enzyme by reacting with 1 sulfhydryl residue. The reaction rate with N-ethylmaleimide was increased by decreasing the pH from neutrality or by the addition of urea. NADH protected against the modification of the sulfhydryl group under all the conditions tested, again suggesting active site specificity for this inactivation. This enzyme has a subunit weight of 33,000 and is a dimer. The native malate dehydrogenase will bind only 1 mol of NADH and it is thus assumed that there is only a single active site per dimer.